Intelligent Materials and Systems Lab - User contributions [en]

User:Gajanee

2021-06-18T08:22:12Z

Gajanee: /* Journal Articles */

{{UserProfile |
fullname=Kaija Põhako-Esko |
picture=Kaija.jpg |
mobile=+372 737-4823 |
email=kaija.pohako@ut.ee |
orcid=0000-0003-1928-5141 |
other=
{{UserProfileItem | Postal address |
IMS Lab
Institute of Technology
Tartu University
Nooruse 1
50411 Tartu
Estonia
}}

}}

[[Category:PI]]

== Publications ==

=== Journal Articles ===

* [https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202102180 Migliorini, L.; Piazzoni, C.; Pohako-Esko, K.; Di Girolamo, M.; Vitaloni, A.; Borghi, F.; Tommaso, S.; Aabloo, A.; Milani, P. All-Printed Green Micro-Supercapacitors Based on a Naturalderived Ionic Liquid for Flexible Transient Electronics. ''Adv. Functs. Mat.'' '''2021''', 2102180.]
* [https://iopscience.iop.org/article/10.1088/1361-665X/ab7f24/meta Elhi, F.; Priks, T.; Rinne, P.; Kaldalu, N.; Zusinaite, E.; Johanson, U.; Aabloo, A.; Tamm, T.; Põhako-Esko, K. Electromechanically active polymer actuators based on biofriendly choline ionic liquids. ''Smart. Mater. Struct..'' '''2020''', 29, 055021.]
* [https://www.mdpi.com/2076-3417/9/24/5367 Karu, K.; Elhi, F.; Põhako-Esko, K.; Ivanistsev, V. Predicting Melting Points of Biofriendly Choline-Based Ionic Liquids with Molecular Dynamics. ''Appl. Sci. '' '''2019''', 24, 5367.]
* Bauer, T., Voggenreiter, M., Xu, T., Wähler, T., Agel, F., Pohako-Esko, K., Schulz, P., Döpper, T., Görling, A., Polarz, S., Wasserscheid, P., Libuda, J. (2017) [http://doi.org/10.1002/zaac.201600345 <nowiki>ZnO Nanoparticle Formation from the Molecular Precursor [MeZnOtBu]</nowiki>{{sub|4}}<nowiki>by Ozone Treatment in Ionic Liquids: in-situ Vibrational Spectroscopy in an Ultrahigh Vacuum Environment</nowiki>], ''Zeitschrift fur Anorganische und Allgemeine Chemie''. [http://doi.org/10.1002/zaac.201600345 http://doi.org/10.1002/zaac.201600345]
* Mehl, S., Bauer, T., Brummel, O., Pohako-Esko, K., Schulz, P., Wasserscheid, P., Libuda, J. (2016) [http://doi.org/10.1021/acs.langmuir.6b02303 <nowiki>Ionic-Liquid-Modified Hybrid Materials Prepared by Physical Vapor Codeposition: Cobalt and Cobalt Oxide Nanoparticles in [C</nowiki>{{sub|1}}<nowiki>C</nowiki>{{sub|2}}<nowiki>Im][OTf] Monitored by in Situ IR Spectroscopy</nowiki>], ''Langmuir''. [http://doi.org/10.1021/acs.langmuir.6b02303 http://doi.org/10.1021/acs.langmuir.6b02303]
* Pohako-Esko, K., Wehner, T., Schulz, P.S., Heinemann, F.W., Müller-Buschbaum, K., Wasserscheid, P. (2016) [http://doi.org/10.1002/ejic.201501454 <nowiki>Synthesis and Properties of Organic Hexahalocerate(III) Salts</nowiki>], ''European Journal of Inorganic Chemistry''. [http://doi.org/10.1002/ejic.201501454 http://doi.org/10.1002/ejic.201501454]
* Brummel, O., Faisal, F., Bauer, T., Pohako-Esko, K., Wasserscheid, P., Libuda, J. (2016) [http://doi.org/10.1016/j.electacta.2015.12.006 <nowiki>Ionic Liquid-Modified Electrocatalysts: The Interaction of [C</nowiki>{{sub|1}}<nowiki>C</nowiki>{{sub|2}}<nowiki>Im][OTf] with Pt(1 1 1) and its Influence on Methanol Oxidation Studied by Electrochemical IR Spectroscopy</nowiki>], ''Electrochimica Acta''. [http://doi.org/10.1016/j.electacta.2015.12.006 http://doi.org/10.1016/j.electacta.2015.12.006]
* Bauer, T., Mehl, S., Brummel, O., Pohako-Esko, K., Wasserscheid, P., Libuda, J. (2016) [http://doi.org/10.1021/acs.jpcc.6b00351 <nowiki>Ligand Effects at Ionic Liquid-Modified Interfaces: Coadsorption of [C</nowiki>{{sub|2}}<nowiki>C</nowiki>{{sub|1}}<nowiki>Im][OTf] and CO on Pd(111)</nowiki>], ''Journal of Physical Chemistry C''. [http://doi.org/10.1021/acs.jpcc.6b00351 http://doi.org/10.1021/acs.jpcc.6b00351]
* Pohako-Esko, K., Bahlmann, M., Schulz, P.S., Wasserscheid, P. (2016) [http://doi.org/10.1021/acs.iecr.6b00862 <nowiki>Chitosan Containing Supported Ionic Liquid Phase Materials for CO</nowiki>{{sub|2}}<nowiki> Absorption</nowiki>], ''Industrial and Engineering Chemistry Research''. [http://doi.org/10.1021/acs.iecr.6b00862 http://doi.org/10.1021/acs.iecr.6b00862]
* Karousos, D.S., Kouvelos, E., Sapalidis, A., Pohako-Esko, K., Bahlmann, M., Schulz, P.S., Wasserscheid, P., Siranidi, E., Vangeli, O., Falaras, P., Kanellopoulos, N., Romanos, G.E. (2016) [http://doi.org/10.1021/acs.iecr.6b00664 <nowiki>Novel Inverse Supported Ionic Liquid Absorbents for Acidic Gas Removal from Flue Gas</nowiki>], ''Industrial and Engineering Chemistry Research''. [http://doi.org/10.1021/acs.iecr.6b00664 http://doi.org/10.1021/acs.iecr.6b00664]
* Koller, T.M., Rausch, M.H., Pohako-Esko, K., Wasserscheid, P., Fröba, A.P. (2015) [http://doi.org/10.1021/acs.jced.5b00303 <nowiki>Surface Tension of Tricyanomethanide- and Tetracyanoborate-Based Imidazolium Ionic Liquids by Using the Pendant Drop Method</nowiki>], ''Journal of Chemical and Engineering Data''. [http://doi.org/10.1021/acs.jced.5b00303 http://doi.org/10.1021/acs.jced.5b00303]
* Tarkanovskaja, M., Välbe, R., Põhako-Esko, K., Mäeorg, U., Reedo, V., Hoop, A., Saal, K., Krumme, A., Kink, I., Heinmaa, I., Lõhmus, A. (2014) [http://doi.org/10.1016/j.ceramint.2013.12.114 <nowiki>Novel homogeneous gel fibers and capillaries from blend of titanium tetrabutoxide and siloxane functionalized ionic liquid</nowiki>], ''Ceramics International''. [http://doi.org/10.1016/j.ceramint.2013.12.114 http://doi.org/10.1016/j.ceramint.2013.12.114]
* Põhako-Esko, K., Taaber, T., Saal, K., Lõhmus, R., Kink, I., Mäeorg, U. (2013) [http://doi.org/10.1080/00397911.2012.745159 <nowiki>New method for synthesis of methacrylate-type polymerizable ionic liquids</nowiki>], ''Synthetic Communications''. [http://doi.org/10.1080/00397911.2012.745159 http://doi.org/10.1080/00397911.2012.745159]
* Shulga, E., Pohako, K., Treshchalov, A., Joost, U., Kisand, V., Kink, I. (2011) [http://doi.org/10.1049/mnl.2011.0357 <nowiki>Functionalisation of aligned carbon nanotubes with nitric acid vapour</nowiki>], ''Micro and Nano Letters''. [http://doi.org/10.1049/mnl.2011.0357 http://doi.org/10.1049/mnl.2011.0357]
* Põhako, K., Saal, K., Bredihhin, A., Kink, I., Mäeorg, U. (2011) [http://doi.org/10.3176/proc.2011.1.07 <nowiki>A new method for the synthesis of 3-hydrazinopropyl trimethoxysilane</nowiki>], ''Proceedings of the Estonian Academy of Sciences''. [http://doi.org/10.3176/proc.2011.1.07 http://doi.org/10.3176/proc.2011.1.07]
* Kessler, F., Szesni, N., Põhako, K., Weibert, B., Fischer, H. (2009) [http://doi.org/10.1021/om800843e <nowiki>Synthesis of the first stable palladium allenylidene complexes</nowiki>], ''Organometallics''. [http://doi.org/10.1021/om800843e http://doi.org/10.1021/om800843e]
* Põhako, K., Saal, K., Kink, I., Bredihhin, A., Mäeorg, U. (2008) [http://www.scopus.com/inward/record.url?eid=2-s2.0-45849105562&partnerID=MN8TOARS <nowiki>Synthesis of allyl hydrazine: A comparative study of different methods</nowiki>], ''Arkivoc''.
* Põhako, K., Mäeorg, U., Saal, K., Kisseljova, K., Bredihhin, A., Kink, I. (2007) [http://doi.org/10.1088/1742-6596/93/1/012032 <nowiki>A route towards a new hydrazino-ormosil</nowiki>], ''Journal of Physics: Conference Series''. [http://doi.org/10.1088/1742-6596/93/1/012032 http://doi.org/10.1088/1742-6596/93/1/012032]

=== Conference Papers ===

* Taaber, T., Põhako-Esko, K., Joost, U., Külasalu, K., Antsov, M., Antonov, M., Veinthal, R., Saal, K., Lõhmus, R., Mäeorg, U. (2014) [http://doi.org/10.1557/opl.2014.539 <nowiki>Covalent coupling of ionic liquid to carbon nanotubes: Preparation and tribological properties</nowiki>], ''Materials Research Society Symposium Proceedings''. [http://doi.org/10.1557/opl.2014.539 http://doi.org/10.1557/opl.2014.539]

People

2021-06-18T08:19:09Z

Gajanee: /* Staff */

{{DISPLAYTITLE:The Lab's Team}} __NOTOC__
== Staff ==

{{Team|
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab (polymer materials)}}
{{TeamMember|Karl|Karl Kruusamäe|associate professor of robotics engineering, [[IMS robotics]]}}
{{TeamMember|Indrekm|Indrek Must|associate professor of soft robotics}}
{{TeamMember|Aks1812|Arun Kumar Singh|associate professor of collaborative robotics, [[IMS robotics]]}}
{{TeamMember|Tarmo|Tarmo Tamm| associate professor of materials science}}
{{TeamMember|Vahur|Vahur Zadin|professor (finite element modelling, molecular dynamics, high electric fields, CERN)}}
{{TeamMember|Heiki|Heiki Kasemägi|associate professor (ion-conducting polymer, computer simulations) & Computer engineering study programme manager}}
{{TeamMember|Gajanee|Kaija Põhako-Esko|associate professor of materials chemistry, former Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Urmas|Urmas Johanson|researcher (electrochemistry)}}
{{TeamMember|Annaliisa|Anna-Liisa Peikolainen|researcher (carbon materials, chemistry)}}
{{TeamMember|Janno|Janno Torop|researcher (flow cell supercaps, carbon materials)}}
{{TeamMember|Saoni|Saoni Banerji| research fellow (CMOS MEMS sensors, mixed-signal ASIC design, microelectronics)}}
{{TeamMember|Morteza.Daneshmand|Morteza Daneshmand|research fellow (human-robot collaboration in manufacturing), [[IMS robotics]]}}
{{TeamMember|Veix|Veiko Vunder|lecturer (robotics)}}
{{TeamMember|Artur|Artur Abels|junior lecturer (digital electronics)}}
{{TeamMember|Rennoraudmae|Renno Raudmäe|junior lecturer (robotics)}}
{{TeamMember|Sandra|Sandra Schumann|robotics education}}
{{TeamMember|Roman|Roman Leinus|engineer (robotics)}}
{{TeamMember|Teet|Teet Tilk|engineer (electronics)}}
{{TeamMember|Tauri|Tauri Tätte|engineer (robotics)}}
{{TeamMember|Kadri.tonnisson|Kadri Tõnnisson|head of administration in IMS Lab}}
{{TeamMember|Kristel.leif|Kristel Leif|communication coordinator}}
{{TeamMember|Anett|Anett Toom|project assistant}}
{{TeamMember|Kirsi|Kirsi Zirel|project assistant}}

}}

== PhD Students ==

{{Team|
{{TeamMember|Arko|Arko Kesküla|PhD student (ionic liquid polymerization); supervisors: A.-L. Peikolainen, U. Mäeorg}}
{{TeamMember|kaur|Kaur Leemets|PhD student (printable sensors)}}
{{TeamMember|Zane|Zane Zondaka|PhD student (Conductive polymers carbon composites)}}
{{TeamMember|Robertvalner|Robert Valner|PhD student (robotics, [[IMS robotics]])}}
{{TeamMember|faiza|Faiza Summer|PhD student (Flow-capacitor)}}
{{TeamMember|Pille|Pille Rinne|PhD student}}
{{TeamMember|madis.harjo|Madis Harjo|PhD student (nanocarbon composites)}}
{{TeamMember|Fred|Fred Elhi|PhD student (microfabrication, EAP)}}
{{TeamMember|hans_priks|Hans Priks|PhD student (conducting polymers)}}
{{TeamMember|Kristiankuppart|Kristian Kuppart|PhD student (MD in high electric fields)}}
{{TeamMember|karlkaru|Karl Karu|PhD student}}
{{TeamMember|Helena.nulk|Helena Nulk|PhD student (collaborative robotics, [[IMS robotics]])}}
{{TeamMember|Ingridre|Ingrid Rebane|PhD student (PDMS foams)}}
{{TeamMember|ye.wang|Ye Wang|PhD student (Design and development of tailored nanostructures)}}
{{TeamMember|Iman.dadras|Iman Dadras|PhD student (Microfabrication)}}
{{TeamMember|Fatemeh.rastgar|Fatemeh Rastgar|PhD student (Robotics)}}
{{TeamMember|yauheni|Yauheni Sarokin|PhD student (Variable stiffness textiles)}}
{{TeamMember|Houman.masnavi|Houman Masnavi|PhD student (deep-learning-based motion-planning in robotics)}}
{{TeamMember|Oleksandr.syzoniuk|Oleksandr Syzoniuk|PhD student (soft robotics)}}

}}

==Students==

{{Team|
{{TeamMember|markus|Markus Loide|student}}
{{TeamMember|Liivak|Martin Liivak|student (FEM simulations of 3D-MB's)}}
{{TeamMember|Priit.poldmaa|Priit Põldmaa|student}}
{{TeamMember|raunoumborg|Rauno Umborg|student (computer engineering)}}
{{TeamMember|Kaarelsiimut|Kaarel Siimut|student (aerated concrete)}}
{{TeamMember|Ingmar.laan|Ingmar Laan|student (ionic polymer actuators)}}
{{TeamMember|Johannes.muru|Johannes Muru|student}}
{{TeamMember|Hermanratas|Herman Klas Ratas|student}}
{{TeamMember|Kadriannvaldur|Kadri-Ann Valdur|student (PPy actuators)}}
{{TeamMember|Ats.aasmaa|Ats Aasmaa|student (modelling of microbatteries)}}
{{TeamMember|Gryogor|Igor Rybalskii|student (robotics)}}
{{TeamMember|Phuong.nguyen|Phuong Nguyen|student (FEM simulations)}}
{{TeamMember|Magnus.kaldjarv|Magnus Kaldjärv|student (soft robotics)}}
{{TeamMember|Mkuuts|Mona Küüts|student (soft robotics)}}
{{TeamMember|Silvia.aabloo|Silvia Hiie Aabloo|student (soft robotics)}}
{{TeamMember|Oleskhen|Hendrik Olesk|student (mobile manipulator robotics)}}
{{TeamMember|Tepandi|Tarvi Tepandi|student (AR in robotics)}}
{{TeamMember|Yigit|Yiğit ORHAN|student (Thermodynamics)}}
{{TeamMember|Eva.m6tsh2rg|Eva Mõtshärg|student (robotics education)}}

}}

==Colleagues==

{{Team|
{{TeamMember|Rosin|Margus Rosin|lecturer (FPGA)}}
{{TeamMember|Frkaasik|Friedrich Kaasik|ex-PhD student (carbon-polymer actuators)}}
{{TeamMember|Heilo|Heilo Altin|educational robotics}}
{{TeamMember|Ramon.rantsus|Ramon Rantsus|educational robotics}}
{{TeamMember|Arturt|Artur Tamm| at LLNL [https://qsg.llnl.gov/node/89.html QSG LLNL]}}
{{TeamMember|Aleksander|Aleksander Tõnnisson|[http://buildit.ee Buildit] (Hardware accelerator) CEO}}
{{TeamMember|katlin.rohtlaid|Kätlin Rohtlaid}}
{{TeamMember|Grecebo|Inga Põldsalu|postdoc at University of Oslo, [https://www.med.uio.no/ncmm/english/people/aca/inga/index.html Bionanotechnology and Membrane Systems]}}
}}

People

2021-06-18T08:18:29Z

Gajanee: /* Staff */

{{DISPLAYTITLE:The Lab's Team}} __NOTOC__
== Staff ==

{{Team|
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab (polymer materials)}}
{{TeamMember|Karl|Karl Kruusamäe|associate professor of robotics engineering, [[IMS robotics]]}}
{{TeamMember|Indrekm|Indrek Must|associate professor of soft robotics}}
{{TeamMember|Aks1812|Arun Kumar Singh|associate professor of collaborative robotics, [[IMS robotics]]}}
{{TeamMember|Tarmo|Tarmo Tamm| associate professor of materials science}}
{{TeamMember|Vahur|Vahur Zadin|professor (finite element modelling, molecular dynamics, high electric fields, CERN)}}
{{TeamMember|Heiki|Heiki Kasemägi|associate professor (ion-conducting polymer, computer simulations) & Computer engineering study programme manager}}
{{TeamMember|Gajanee|Kaija Põhako-Esko|associate professor, former Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Urmas|Urmas Johanson|researcher (electrochemistry)}}
{{TeamMember|Annaliisa|Anna-Liisa Peikolainen|researcher (carbon materials, chemistry)}}
{{TeamMember|Janno|Janno Torop|researcher (flow cell supercaps, carbon materials)}}
{{TeamMember|Saoni|Saoni Banerji| research fellow (CMOS MEMS sensors, mixed-signal ASIC design, microelectronics)}}
{{TeamMember|Morteza.Daneshmand|Morteza Daneshmand|research fellow (human-robot collaboration in manufacturing), [[IMS robotics]]}}
{{TeamMember|Veix|Veiko Vunder|lecturer (robotics)}}
{{TeamMember|Artur|Artur Abels|junior lecturer (digital electronics)}}
{{TeamMember|Rennoraudmae|Renno Raudmäe|junior lecturer (robotics)}}
{{TeamMember|Sandra|Sandra Schumann|robotics education}}
{{TeamMember|Roman|Roman Leinus|engineer (robotics)}}
{{TeamMember|Teet|Teet Tilk|engineer (electronics)}}
{{TeamMember|Tauri|Tauri Tätte|engineer (robotics)}}
{{TeamMember|Kadri.tonnisson|Kadri Tõnnisson|head of administration in IMS Lab}}
{{TeamMember|Kristel.leif|Kristel Leif|communication coordinator}}
{{TeamMember|Anett|Anett Toom|project assistant}}
{{TeamMember|Kirsi|Kirsi Zirel|project assistant}}

}}

== PhD Students ==

{{Team|
{{TeamMember|Arko|Arko Kesküla|PhD student (ionic liquid polymerization); supervisors: A.-L. Peikolainen, U. Mäeorg}}
{{TeamMember|kaur|Kaur Leemets|PhD student (printable sensors)}}
{{TeamMember|Zane|Zane Zondaka|PhD student (Conductive polymers carbon composites)}}
{{TeamMember|Robertvalner|Robert Valner|PhD student (robotics, [[IMS robotics]])}}
{{TeamMember|faiza|Faiza Summer|PhD student (Flow-capacitor)}}
{{TeamMember|Pille|Pille Rinne|PhD student}}
{{TeamMember|madis.harjo|Madis Harjo|PhD student (nanocarbon composites)}}
{{TeamMember|Fred|Fred Elhi|PhD student (microfabrication, EAP)}}
{{TeamMember|hans_priks|Hans Priks|PhD student (conducting polymers)}}
{{TeamMember|Kristiankuppart|Kristian Kuppart|PhD student (MD in high electric fields)}}
{{TeamMember|karlkaru|Karl Karu|PhD student}}
{{TeamMember|Helena.nulk|Helena Nulk|PhD student (collaborative robotics, [[IMS robotics]])}}
{{TeamMember|Ingridre|Ingrid Rebane|PhD student (PDMS foams)}}
{{TeamMember|ye.wang|Ye Wang|PhD student (Design and development of tailored nanostructures)}}
{{TeamMember|Iman.dadras|Iman Dadras|PhD student (Microfabrication)}}
{{TeamMember|Fatemeh.rastgar|Fatemeh Rastgar|PhD student (Robotics)}}
{{TeamMember|yauheni|Yauheni Sarokin|PhD student (Variable stiffness textiles)}}
{{TeamMember|Houman.masnavi|Houman Masnavi|PhD student (deep-learning-based motion-planning in robotics)}}
{{TeamMember|Oleksandr.syzoniuk|Oleksandr Syzoniuk|PhD student (soft robotics)}}

}}

==Students==

{{Team|
{{TeamMember|markus|Markus Loide|student}}
{{TeamMember|Liivak|Martin Liivak|student (FEM simulations of 3D-MB's)}}
{{TeamMember|Priit.poldmaa|Priit Põldmaa|student}}
{{TeamMember|raunoumborg|Rauno Umborg|student (computer engineering)}}
{{TeamMember|Kaarelsiimut|Kaarel Siimut|student (aerated concrete)}}
{{TeamMember|Ingmar.laan|Ingmar Laan|student (ionic polymer actuators)}}
{{TeamMember|Johannes.muru|Johannes Muru|student}}
{{TeamMember|Hermanratas|Herman Klas Ratas|student}}
{{TeamMember|Kadriannvaldur|Kadri-Ann Valdur|student (PPy actuators)}}
{{TeamMember|Ats.aasmaa|Ats Aasmaa|student (modelling of microbatteries)}}
{{TeamMember|Gryogor|Igor Rybalskii|student (robotics)}}
{{TeamMember|Phuong.nguyen|Phuong Nguyen|student (FEM simulations)}}
{{TeamMember|Magnus.kaldjarv|Magnus Kaldjärv|student (soft robotics)}}
{{TeamMember|Mkuuts|Mona Küüts|student (soft robotics)}}
{{TeamMember|Silvia.aabloo|Silvia Hiie Aabloo|student (soft robotics)}}
{{TeamMember|Oleskhen|Hendrik Olesk|student (mobile manipulator robotics)}}
{{TeamMember|Tepandi|Tarvi Tepandi|student (AR in robotics)}}
{{TeamMember|Yigit|Yiğit ORHAN|student (Thermodynamics)}}
{{TeamMember|Eva.m6tsh2rg|Eva Mõtshärg|student (robotics education)}}

}}

==Colleagues==

{{Team|
{{TeamMember|Rosin|Margus Rosin|lecturer (FPGA)}}
{{TeamMember|Frkaasik|Friedrich Kaasik|ex-PhD student (carbon-polymer actuators)}}
{{TeamMember|Heilo|Heilo Altin|educational robotics}}
{{TeamMember|Ramon.rantsus|Ramon Rantsus|educational robotics}}
{{TeamMember|Arturt|Artur Tamm| at LLNL [https://qsg.llnl.gov/node/89.html QSG LLNL]}}
{{TeamMember|Aleksander|Aleksander Tõnnisson|[http://buildit.ee Buildit] (Hardware accelerator) CEO}}
{{TeamMember|katlin.rohtlaid|Kätlin Rohtlaid}}
{{TeamMember|Grecebo|Inga Põldsalu|postdoc at University of Oslo, [https://www.med.uio.no/ncmm/english/people/aca/inga/index.html Bionanotechnology and Membrane Systems]}}
}}

Ionic Liquids

2021-06-18T08:17:19Z

Gajanee: /* Primary contact */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|Associate Prof. of Materials Chemistry, former Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Development of biocompatible ionic electromechanically active polymer actuators and sensors using biofriendly ionic liquids as electrolytes (Marie Sklodowska-Curie Individual Fellowship no 793377 "BIOACT" )
* Development of multi-stimuli responsive materials and devices using magnetic ionic liquids

=== Selected Publications ===

* [https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202102180 Migliorini, L.; Piazzoni, C.; Pohako-Esko, K.; Di Girolamo, M.; Vitaloni, A.; Borghi, F.; Tommaso, S.; Aabloo, A.; Milani, P. All-Printed Green Micro-Supercapacitors Based on a Naturalderived Ionic Liquid for Flexible Transient Electronics. ''Adv. Functs. Mat.'' '''2021''', 2102180.]
* [https://iopscience.iop.org/article/10.1088/1361-665X/ab7f24/meta Elhi, F.; Priks, T.; Rinne, P.; Kaldalu, N.; Zusinaite, E.; Johanson, U.; Aabloo, A.; Tamm, T.; Põhako-Esko, K. Electromechanically active polymer actuators based on biofriendly choline ionic liquids. ''Smart. Mater. Struct..'' '''2020''', 29, 055021.]
* [https://www.mdpi.com/2076-3417/9/24/5367 Karu, K.; Elhi, F.; Põhako-Esko, K.; Ivanistsev, V. Predicting Melting Points of Biofriendly Choline-Based Ionic Liquids with Molecular Dynamics. ''Appl. Sci. '' '''2019''', 24, 5367.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]

Ionic Liquids

2021-06-18T08:15:46Z

Gajanee: /* Projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Development of biocompatible ionic electromechanically active polymer actuators and sensors using biofriendly ionic liquids as electrolytes (Marie Sklodowska-Curie Individual Fellowship no 793377 "BIOACT" )
* Development of multi-stimuli responsive materials and devices using magnetic ionic liquids

=== Selected Publications ===

* [https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202102180 Migliorini, L.; Piazzoni, C.; Pohako-Esko, K.; Di Girolamo, M.; Vitaloni, A.; Borghi, F.; Tommaso, S.; Aabloo, A.; Milani, P. All-Printed Green Micro-Supercapacitors Based on a Naturalderived Ionic Liquid for Flexible Transient Electronics. ''Adv. Functs. Mat.'' '''2021''', 2102180.]
* [https://iopscience.iop.org/article/10.1088/1361-665X/ab7f24/meta Elhi, F.; Priks, T.; Rinne, P.; Kaldalu, N.; Zusinaite, E.; Johanson, U.; Aabloo, A.; Tamm, T.; Põhako-Esko, K. Electromechanically active polymer actuators based on biofriendly choline ionic liquids. ''Smart. Mater. Struct..'' '''2020''', 29, 055021.]
* [https://www.mdpi.com/2076-3417/9/24/5367 Karu, K.; Elhi, F.; Põhako-Esko, K.; Ivanistsev, V. Predicting Melting Points of Biofriendly Choline-Based Ionic Liquids with Molecular Dynamics. ''Appl. Sci. '' '''2019''', 24, 5367.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]

Ionic Liquids

2021-06-18T08:11:08Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Development of biocompatible ionic electromechanically active polymer actuators and sensors using biofriendly ionic liquids as electrolytes
* Development of multi-stimuli responsive materials and devices using magnetic ionic liquids

=== Selected Publications ===

* [https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202102180 Migliorini, L.; Piazzoni, C.; Pohako-Esko, K.; Di Girolamo, M.; Vitaloni, A.; Borghi, F.; Tommaso, S.; Aabloo, A.; Milani, P. All-Printed Green Micro-Supercapacitors Based on a Naturalderived Ionic Liquid for Flexible Transient Electronics. ''Adv. Functs. Mat.'' '''2021''', 2102180.]
* [https://iopscience.iop.org/article/10.1088/1361-665X/ab7f24/meta Elhi, F.; Priks, T.; Rinne, P.; Kaldalu, N.; Zusinaite, E.; Johanson, U.; Aabloo, A.; Tamm, T.; Põhako-Esko, K. Electromechanically active polymer actuators based on biofriendly choline ionic liquids. ''Smart. Mater. Struct..'' '''2020''', 29, 055021.]
* [https://www.mdpi.com/2076-3417/9/24/5367 Karu, K.; Elhi, F.; Põhako-Esko, K.; Ivanistsev, V. Predicting Melting Points of Biofriendly Choline-Based Ionic Liquids with Molecular Dynamics. ''Appl. Sci. '' '''2019''', 24, 5367.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]

Ionic Liquids

2019-09-12T10:56:15Z

Gajanee: /* Projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Development of biocompatible ionic electromechanically active polymer actuators and sensors using biofriendly ionic liquids as electrolytes
* Development of multi-stimuli responsive materials and devices using magnetic ionic liquids

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2019-09-12T10:53:24Z

Gajanee: /* Highlights */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2019-09-12T10:52:09Z

Gajanee: /* Student projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2019-09-12T10:49:24Z

Gajanee: /* Student projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==

{{Team|
{{TeamMember|Gajanee|Kaija Põhako-Esko|researcher, Marie Skłodowska-Curie fellow (chemistry, organic synthesis, ionic liquids)}}
{{TeamMember|Alvo|Alvo Aabloo|professor, head of the lab}}
}}

== Student projects ==
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Biocompatible electroactive polymers]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Low-temperature thermostat (Proline)

2019-01-30T11:44:47Z

Gajanee: /* Booking list */

=='''Booking list'''==

'''NB! Newer bookings on top!''' 

{| class="wikitable"
!colspan="6"|Booking list
|-
|'''User'''
|'''Date'''
|'''Time'''
|-
|Kaija
|31.01.2019
|10:00 - 16:00
|-
|Hans
|29.01.2019 - 30.01.2019
|9:00 - 18:00
|-
|Pille
|26-27.01.2019
|18.00-10.00
|-
|Georg
|24.01 - 25.01
|19:00 - 08:00
|-
|Kadri-Ann
|22-23.01.2019
|19:00 - 9:00
|-
|Georg Niit
|16-17.01.2019
|15.00-9.00
|-
|Hans
|07.01.2019
|10:00-17:00
|-
|Hans
|13-14.12.2018
|10.00-14.00
|-
|Kadri-Ann
|10-11.12.2018
|16.00-10.30
|-
|Pille
|28-29.11.2018
|18.00-10.00
|-
|Pille
|27-28.11.2018
|18.00-10.00
|-
|Kadri-Ann
|23-24.11.2018
|16.00-12.00
|-
|Pille
|22-23.11.2018
|18.00-10.00
|-
|Madis
|20-21.11.2018
|18.00-08.00
|-
|Hans
|14-15.11.2018
|8.00-17.00
|-
|Kadri-Ann
|12-13.11.2018
|16.00-10.00
|-
|Kadri-Ann
|8-9.11.2018
|16.00-10.00
|-
|Pille
|01.11.2018-02.11.2018
|17.00-09.00
|-
|Pille
|31.10.2018-01.11.2018
|17.00-09.00
|-
|Kadri-Ann
|29.10.2018-30.10.2018
|16.00-10.00
|-
|Pille
|28.10.2018-29.10.2018
|17.00-09.00
|-
|Hans
|25.10.2018-26.10.2018
|10:00-09.00
|-
|Pille
|23.10.2018-24.10.2018
|17.00-09.00
|-
|Pille
|22.10.2018-23.10.2018
|11.00-09.00
|-
|Pille
|20.10.2018-22.10.2018
|17.00-09.00
|-
|Hans
|18.10.2018-20.10.2018
|12.00-12.00
|-
|Madis
|17.10.2018-18.10.2018
|18:00 - 08.00
|-
|Hans
|16.10.2018-17.10.2018
|8.00-9.00
|-
|Pille
|15.10.2018-16.10.2018
|17:00 - 08.00
|-
|Pille
|13.10.2018-15.10.2018
|12:00 - 10.00
|-
|Pille
|12.10.2018-13.10.2018
|19:00 - 10.00
|-
|Hans
|10.10.2018-11.10.2018
|9.00-9.00
|-
|Pille
|09.10.2018-10.10.2018
|18:00 - 09.00
|-
|Pille
|08.10.2018
|16:00 - 10.00
|-
|Kadri-Ann
|04.10.2018-05.10.2018
|16.00-10.00
|-
|Kadri-Ann
|27.09.2018-28.09.2018
|18.30-09.30
|-
|Kadri-Ann
|19.09.2018-20.09.2018
|16.00-09.00
|-
|Pille
|18.09.2018-19.09.2018
|17:00 - 10.00
|-
|Pille
|18.09.2018
|10:00 - 17.00
|-
|Pille
|14.09.2018-15.09.2018
|9:00 - 11.00
|-
|Pille
|31.08.2018-01.09.2018
|18:00 - 10.00
|-
|Pille
|30.08.2018-31.08.2018
|17:00 - 13.00
|-
|Pille
|27.08.2018
|10:00 - 19.00
|-
|Pille
|23.08.2018 - 24.08.2018
|15:30 - 09.00
|-
|Hans
|23.08.2018
|10:00 - 15.30
|-
|Pille
|22.08.2018-23.08.2018
|17:00 - 10.00
|-
|Pille
|21.08.2018-22.08.2018
|15:00 - 10.00
|-
|Pille
|19.08.2018-20.08.2018
|18:30 - 12.00
|-
|Pille
|17.08.2018-18.08.2018
|16:30 - 12.00
|-
|Hans
|17.08.2018
|9:00 - 17:00
|-
|Jelena
|13.08.2018
|11:00 - 19.00
|-
|Jelena
|10.08.2018
|12:00 - 19.00
|-
|Fred
|9.08.2018
|10:00 - 14:30
|-
|Fred
|7.08.2018
|10:00 - 14:30
|-
|Fred
|6.08.2018
|17:30 - 19:30
|-
|Fred
|31.07.2018
|11:00 - 14:30
|-
|Fred
|20.06.2018
|12:00 - 17:00
|-
|Kadri
|18.06.2018
|16:00 - 10:30
|-
|Fred
|07.06.2018
|14:00 - 18:00
|-
|Kadri
|28.05.2018-29.05.2018
|14.00-9.30
|-
|Pille
|26.05.2018-28.05.2018
|14:00 - 11:00
|-
|Pille
|14.05.2018
|17:00 - 09:00
|-
|Victor
|27.04.2018
|10:00 - 20:30
|-
|Victor
|26.04.2018
|12:00 - 20:30
|-
|Kadri
|25.04.2018 -26.04.2018
|17:00 - 11:00
|-
|Victor
|24.04.2018
|09:30 - 20:30
|-
|Victor
|23.04.2018
|09:30 - 20:30
|-
|Victor
|23.02.2018
|10:00 - 17:00
|-
|Victor
|22.02.2018
|10:00 - 17:00
|-
|Fred
|21.02.2018
|10:00 - 17:00
|-
|Victor
|17.02.2018
|9:00 - 17:00
|-
|Victor
|16.02.2018
|9:00 - 17:00
|-
|Fred
|15.02.2018
|10:00 - 17:00
|-
|Pille
|11.02.-12.02.2018
|10:00 - 10:00
|-
|Pille
|10.02.-11.02.2018
|10:00 - 10:00
|-
|Pille
|09.02.-10.02.2018
|10:00 - 10:00
|-
|Fred
|8.02.2018
|10:00 - 17:00
|-
|Arko
|7.02 - 08.02.2018
|12:00 - 10:00
|-
||Victor Pascual
|02.01-2018
|12:00-14:00
|-
||Victor Pascual
|30.01-2018
|00:00-24:00
|-
||Sunjai
|17.12-2017-05.01.2018
|00:00-24:00
|-
||Sunjai
|18.03-25.03(1 week in clean room)
|00:00-24:00
|-
||Madis
|06.02-07.02
|21:00-11:00
|-
||Madis
|31.01-01.02
|20:00-10:00
|-
||Madis
|05.12-06.12
|14:00-10:00
|-
|Paul
|11.07.2016
|11.00-22.00
|-
|Sunjai
|21.06.2016 - 24.06
|09.00-00.00
|-
|Paul
|04.03.2016 - 05.03
|16.00-16.00
|-
|Paul
|18.01.2015 - 19.01
|16.00-10.00
|-
|Madis
|06.12.2015-07.12.2015
|19.00 - 9.00
|-
|Paul
|18.11.2015-19.11.2015
|16.00 - 10.00
|-
|Paul/Georg
|14.10.2015 - 15.10.2015
|17.00-10.00
|-
|Hans
|15.09.2015 - 16.09.2015
|10:00-15:00
|-
|Hans
|08.09.2015 - 10.09.2015
|15:00-21:00
|-
|Hans
|01.09.2015 - 02.09.2015
|15:00-21:00
|-
|Paul
|02.07.2015-03.07.2015
|15.00-19.00
|-
|Arko
|26.05 - 27.05.2015
|17:00 - 10:00
|-
|Kätlin
|06.05.2015
|11.00 - 00.00
|-
|Kätlin
|22.04.2015 - 23.04.2015
|13.00 - 10.00
|-
|Madis
|15.04.2015 - 16.04.2015
|21.30-10.00
|-
|Anna-Liisa
|20.03.2015
|9.00-16.00
|-
|Anna-Liisa
|19.03.2015
|11.00-15.00
|-
|Paul
|09.03.2015-10.03.2015
|15.00-12.00 (10.03.2015)
|-
|Madis
|26.01.2015
|16:00-24:00
|-
|Anna-Liisa
|19.01.2015
|9:00-15:00
|-
|Anna-Liisa
|16.01.2015
|9:00-15:00
|-
|Anna-Liisa
|14.01.2015
|13:00-22:00
|-
|Madis
|09.01.2015 12:00 - 13.01.2015 18:00
|
|-
|Rauno
|07.01.2015 18:00 - 08.01.2015 19:00
|-
|----||
|-
|Anna-Liisa
|24.09.2014
|15:00-19:00
|-
|Kätlin
|25.09.2014
|16:00-24:00
|-
|Madis
|02.10.2014
|12:00-15:00
|-
|Madis
|06.10.2014
|12:00-14:00
|-
|Kätlin
|16.10.2014
|15:00-24.00
|-
|Paul
|17.11.2014
|13.00-24.00
|-
|Madis
|18.11.2014
|13.00-24.00
|-
|Madis
|19.11.2014
|09.00-22.00
|-
|Kätlin
|20.11.2014
|11:00-24:00
|-
|Anna-Liisa
|21.11.2014
|09:00-12:00
|-
|Anna-Liisa
|26.11.2014
|14:00-19:00
|-
|Anna-Liisa
|02.12.2014
|11:00-16:00
|-
|Anna-Liisa
|03.12.2014
|14:00-19:00
|-
|Kätlin
|05.12.2014
|00:00-24:00
|-
|Anna-Liisa
|17.12.2014
|13:00-20:00
|-
|Madis
|18.12.2014
|12:00-24:00
|-
|Anna-Liisa
|22.12.2014
|12:00-18:00
|-

Low-temperature thermostat (Proline)

2019-01-30T11:44:22Z

Gajanee: /* Booking list */

=='''Booking list'''==

'''NB! Newer bookings on top!''' 

{| class="wikitable"
!colspan="6"|Booking list
|-
|'''User'''
|'''Date'''
|'''Time'''
|-
|Kaija
|31.01.2019 - 31.01.2019
|10:00 - 16:00
|-
|Hans
|29.01.2019 - 30.01.2019
|9:00 - 18:00
|-
|Pille
|26-27.01.2019
|18.00-10.00
|-
|Georg
|24.01 - 25.01
|19:00 - 08:00
|-
|Kadri-Ann
|22-23.01.2019
|19:00 - 9:00
|-
|Georg Niit
|16-17.01.2019
|15.00-9.00
|-
|Hans
|07.01.2019
|10:00-17:00
|-
|Hans
|13-14.12.2018
|10.00-14.00
|-
|Kadri-Ann
|10-11.12.2018
|16.00-10.30
|-
|Pille
|28-29.11.2018
|18.00-10.00
|-
|Pille
|27-28.11.2018
|18.00-10.00
|-
|Kadri-Ann
|23-24.11.2018
|16.00-12.00
|-
|Pille
|22-23.11.2018
|18.00-10.00
|-
|Madis
|20-21.11.2018
|18.00-08.00
|-
|Hans
|14-15.11.2018
|8.00-17.00
|-
|Kadri-Ann
|12-13.11.2018
|16.00-10.00
|-
|Kadri-Ann
|8-9.11.2018
|16.00-10.00
|-
|Pille
|01.11.2018-02.11.2018
|17.00-09.00
|-
|Pille
|31.10.2018-01.11.2018
|17.00-09.00
|-
|Kadri-Ann
|29.10.2018-30.10.2018
|16.00-10.00
|-
|Pille
|28.10.2018-29.10.2018
|17.00-09.00
|-
|Hans
|25.10.2018-26.10.2018
|10:00-09.00
|-
|Pille
|23.10.2018-24.10.2018
|17.00-09.00
|-
|Pille
|22.10.2018-23.10.2018
|11.00-09.00
|-
|Pille
|20.10.2018-22.10.2018
|17.00-09.00
|-
|Hans
|18.10.2018-20.10.2018
|12.00-12.00
|-
|Madis
|17.10.2018-18.10.2018
|18:00 - 08.00
|-
|Hans
|16.10.2018-17.10.2018
|8.00-9.00
|-
|Pille
|15.10.2018-16.10.2018
|17:00 - 08.00
|-
|Pille
|13.10.2018-15.10.2018
|12:00 - 10.00
|-
|Pille
|12.10.2018-13.10.2018
|19:00 - 10.00
|-
|Hans
|10.10.2018-11.10.2018
|9.00-9.00
|-
|Pille
|09.10.2018-10.10.2018
|18:00 - 09.00
|-
|Pille
|08.10.2018
|16:00 - 10.00
|-
|Kadri-Ann
|04.10.2018-05.10.2018
|16.00-10.00
|-
|Kadri-Ann
|27.09.2018-28.09.2018
|18.30-09.30
|-
|Kadri-Ann
|19.09.2018-20.09.2018
|16.00-09.00
|-
|Pille
|18.09.2018-19.09.2018
|17:00 - 10.00
|-
|Pille
|18.09.2018
|10:00 - 17.00
|-
|Pille
|14.09.2018-15.09.2018
|9:00 - 11.00
|-
|Pille
|31.08.2018-01.09.2018
|18:00 - 10.00
|-
|Pille
|30.08.2018-31.08.2018
|17:00 - 13.00
|-
|Pille
|27.08.2018
|10:00 - 19.00
|-
|Pille
|23.08.2018 - 24.08.2018
|15:30 - 09.00
|-
|Hans
|23.08.2018
|10:00 - 15.30
|-
|Pille
|22.08.2018-23.08.2018
|17:00 - 10.00
|-
|Pille
|21.08.2018-22.08.2018
|15:00 - 10.00
|-
|Pille
|19.08.2018-20.08.2018
|18:30 - 12.00
|-
|Pille
|17.08.2018-18.08.2018
|16:30 - 12.00
|-
|Hans
|17.08.2018
|9:00 - 17:00
|-
|Jelena
|13.08.2018
|11:00 - 19.00
|-
|Jelena
|10.08.2018
|12:00 - 19.00
|-
|Fred
|9.08.2018
|10:00 - 14:30
|-
|Fred
|7.08.2018
|10:00 - 14:30
|-
|Fred
|6.08.2018
|17:30 - 19:30
|-
|Fred
|31.07.2018
|11:00 - 14:30
|-
|Fred
|20.06.2018
|12:00 - 17:00
|-
|Kadri
|18.06.2018
|16:00 - 10:30
|-
|Fred
|07.06.2018
|14:00 - 18:00
|-
|Kadri
|28.05.2018-29.05.2018
|14.00-9.30
|-
|Pille
|26.05.2018-28.05.2018
|14:00 - 11:00
|-
|Pille
|14.05.2018
|17:00 - 09:00
|-
|Victor
|27.04.2018
|10:00 - 20:30
|-
|Victor
|26.04.2018
|12:00 - 20:30
|-
|Kadri
|25.04.2018 -26.04.2018
|17:00 - 11:00
|-
|Victor
|24.04.2018
|09:30 - 20:30
|-
|Victor
|23.04.2018
|09:30 - 20:30
|-
|Victor
|23.02.2018
|10:00 - 17:00
|-
|Victor
|22.02.2018
|10:00 - 17:00
|-
|Fred
|21.02.2018
|10:00 - 17:00
|-
|Victor
|17.02.2018
|9:00 - 17:00
|-
|Victor
|16.02.2018
|9:00 - 17:00
|-
|Fred
|15.02.2018
|10:00 - 17:00
|-
|Pille
|11.02.-12.02.2018
|10:00 - 10:00
|-
|Pille
|10.02.-11.02.2018
|10:00 - 10:00
|-
|Pille
|09.02.-10.02.2018
|10:00 - 10:00
|-
|Fred
|8.02.2018
|10:00 - 17:00
|-
|Arko
|7.02 - 08.02.2018
|12:00 - 10:00
|-
||Victor Pascual
|02.01-2018
|12:00-14:00
|-
||Victor Pascual
|30.01-2018
|00:00-24:00
|-
||Sunjai
|17.12-2017-05.01.2018
|00:00-24:00
|-
||Sunjai
|18.03-25.03(1 week in clean room)
|00:00-24:00
|-
||Madis
|06.02-07.02
|21:00-11:00
|-
||Madis
|31.01-01.02
|20:00-10:00
|-
||Madis
|05.12-06.12
|14:00-10:00
|-
|Paul
|11.07.2016
|11.00-22.00
|-
|Sunjai
|21.06.2016 - 24.06
|09.00-00.00
|-
|Paul
|04.03.2016 - 05.03
|16.00-16.00
|-
|Paul
|18.01.2015 - 19.01
|16.00-10.00
|-
|Madis
|06.12.2015-07.12.2015
|19.00 - 9.00
|-
|Paul
|18.11.2015-19.11.2015
|16.00 - 10.00
|-
|Paul/Georg
|14.10.2015 - 15.10.2015
|17.00-10.00
|-
|Hans
|15.09.2015 - 16.09.2015
|10:00-15:00
|-
|Hans
|08.09.2015 - 10.09.2015
|15:00-21:00
|-
|Hans
|01.09.2015 - 02.09.2015
|15:00-21:00
|-
|Paul
|02.07.2015-03.07.2015
|15.00-19.00
|-
|Arko
|26.05 - 27.05.2015
|17:00 - 10:00
|-
|Kätlin
|06.05.2015
|11.00 - 00.00
|-
|Kätlin
|22.04.2015 - 23.04.2015
|13.00 - 10.00
|-
|Madis
|15.04.2015 - 16.04.2015
|21.30-10.00
|-
|Anna-Liisa
|20.03.2015
|9.00-16.00
|-
|Anna-Liisa
|19.03.2015
|11.00-15.00
|-
|Paul
|09.03.2015-10.03.2015
|15.00-12.00 (10.03.2015)
|-
|Madis
|26.01.2015
|16:00-24:00
|-
|Anna-Liisa
|19.01.2015
|9:00-15:00
|-
|Anna-Liisa
|16.01.2015
|9:00-15:00
|-
|Anna-Liisa
|14.01.2015
|13:00-22:00
|-
|Madis
|09.01.2015 12:00 - 13.01.2015 18:00
|
|-
|Rauno
|07.01.2015 18:00 - 08.01.2015 19:00
|-
|----||
|-
|Anna-Liisa
|24.09.2014
|15:00-19:00
|-
|Kätlin
|25.09.2014
|16:00-24:00
|-
|Madis
|02.10.2014
|12:00-15:00
|-
|Madis
|06.10.2014
|12:00-14:00
|-
|Kätlin
|16.10.2014
|15:00-24.00
|-
|Paul
|17.11.2014
|13.00-24.00
|-
|Madis
|18.11.2014
|13.00-24.00
|-
|Madis
|19.11.2014
|09.00-22.00
|-
|Kätlin
|20.11.2014
|11:00-24:00
|-
|Anna-Liisa
|21.11.2014
|09:00-12:00
|-
|Anna-Liisa
|26.11.2014
|14:00-19:00
|-
|Anna-Liisa
|02.12.2014
|11:00-16:00
|-
|Anna-Liisa
|03.12.2014
|14:00-19:00
|-
|Kätlin
|05.12.2014
|00:00-24:00
|-
|Anna-Liisa
|17.12.2014
|13:00-20:00
|-
|Madis
|18.12.2014
|12:00-24:00
|-
|Anna-Liisa
|22.12.2014
|12:00-18:00
|-

Potentiostat booking (PARstat)

2019-01-30T11:43:06Z

Gajanee: /* Booking list */

=='''Booking list'''==

'''NB! Newer bookings on top!''' 

{| class="wikitable"
!colspan="6"|Booking list
|-
|Kaija
|31.01.2019
|10.00-16.00
|-
|Kadri-Ann
|30.01.2019
|11.00-14.00
|-
|Fr. Krull
|29.01.2019
|9.30-13.00
|-
|Fr. Krull
|28.01.2019
|12.30-15.00
|-
|Pille
|26-27.01.2019
|09.00-19.00
|-
|Georg
|24.01 - 25.01
|19:00 - 08:00
|-
|Kadri-Ann
|22-23.01.2019
|19:00 - 9:00
|-
|Georg
|21-22.01.2019
|17:00 - 09:00
|-
|Fr. Krull
|21.01.2019
|10:30 - 11:30
|-
|Pille
|19-20.01.2019
|09.00-19.00
|-
|Georg Niit
|16-17.01.2019
|15.00-9.00
|-
|Friedrich Kr
|16.01.2019
|10:00-14.00
|-
|Georg Niit
|15.01 - 16.01
|17:00 - 11:00
|-
|Friedrich Krull
|09.01.2019
|13.30-15.30
|-
|Friedrich Krull
|07.01.2019
|14.00-16.00
|-
|Pille
|18-19.12.2018
|19.00-09.00
|-
|Pille
|17-18.12.2018
|19.00-09.00
|-
|Pille
|15-16.12.2018
|10.00-19.00
|-
|Pille
|13.12.2018
|17.00-19.00
|-
|Jelena
|11.12.2018
|10.30-17.00
|-
|Kadri-Ann
|10-11.12.2018
|16.00-10.30
|-
|Jelena
|7.12.2018
|15.15-19.00
|-
|Jelena
|5.12.2018
|14.15-19.00
|-
|Jelena
|3.12.2018
|13.30-19.00
|-
|Kadri-Ann
|03.12.2018
|11.00-13.30
|-
|Pille
|28-29.11.2018
|18.00-10.00
|-
|Kadri-Ann
|28.11.2018
|10.00-14.00
|-
|Pille
|27-28.11.2018
|18.00-10.00
|-
|Kadri-Ann
|26.11.2018
|12.00-15.00
|-
|Kadri-Ann
|23-24.11.2018
|16.00-12.00
|-
|Pille
|22-23.11.2018
|16.00-10.00
|-
|Madis
|20-21.11.2018
|18.00-08.00
|-
|Kadri-Ann
|12-13.11.2018
|16.00-10.00
|-
|Pille
|10.11.2018-12.11.2018
|10.00-09.00
|-
|Jelena
|9.11.2018
|15.00-21.00
|-
|Kadri-Ann
|8-9.11.2018
|16.00-10.00
|-
|Pille
|08.11.2018
|08.00-11.00
|-
|Jelena
|7.11.2018
|16.00-20.00
|-
|Pille
|07.11.2018
|08.00-12.00
|-
|Pille
|06.11.2018
|09.00-18.00
|-
|Pille
|05.11.2018
|08.00-17.00
|-
|Jelena
|2.11.2018
|14.00-19.00
|-
|Pille
|02.11.2018
|09.00-14.00
|-
|Pille
|01.11.2018-02.11.2018
|17.00-09.00
|-
|Pille
|31.10.2018-01.11.2018
|17.00-09.00
|-
|Pille
|30.10.2018
|14.00-18.00
|-
|Kadri-Ann
|29.10.2018-30.10.2018
|16.00-10.00
|-
|Pille
|28.10.2018-29.10.2018
|17.00-09.00
|-
|Pille
|25.10.2018
|09.00-19.00
|-
|Pille
|24.10.2018
|09.00-19.00
|-
|Pille
|23.10.2018-24.10.2018
|17.00-09.00
|-
|Jelena
|23.10.2018
|10.30-16.00
|-
|Pille
|22.10.2018-23.10.2018
|11.00-09.00
|-
|Pille
|19.10.2018-22.10.2018
|22.00-09.00
|-
|Verner
|19.10.2018
|08.00-22.00
|-
|Jelena
|18.10.2018
|10.30-16.00
|-
|Madis
|17.10.2018-18.10.2018
|18:00 - 08.00
|-
|Pille
|16.10.2018-17.10.2018
|19:00 - 08.00
|-
|Pille
|15.10.2018-16.10.2018
|17:00 - 08.00
|-
|Pille
|13.10.2018-15.10.2018
|12:00 - 10.00
|-
|Pille
|12.10.2018-13.10.2018
|19:00 - 10.00
|-
|Pille
|10.10.2018
|10:00 - 18.00
|-
|Pille
|09.10.2018-10.10.2018
|10:00 - 10.00
|-
|Pille
|08.10.2018
|16:00 - 23.30
|-
|Pille
|07.10.2018
|13:00 - 19.00
|-
|Sunjai
|05.10.2018
|20:00 - 20.30
|-
|Jelena
|05.10.2018
|11:00 - 17.00
|-
|Kadri-Ann
|04.10.2018-05.10.2018
|16.00-10.00
|-
|Verner
|04.10.2018
|09:00 - 16.00
|-
|Verner
|02.10.2018
|09:00 - 16.00
|-
|Pille
|01.10.2018
|11:00 - 12.00
|-
|Pille
|29.09.2018
|12:30 - 18.00
|-
|Kadri-Ann
|27.09.2018-28.09.2018
|18.30-09.30
|-
|Pille
|27.09.2018
|09:00 - 18.00
|-
|Pille
|26.09.2018
|09:00 - 18.00
|-
|Pille
|25.09.2018
|09:00 - 18.00
|-
|Pille
|24.09.2018
|09:00 - 18.00
|-
|Pille
|21.09.2018
|10:30 - 18.00
|-
|Kadri-Ann
|19.09.2018-20.09.2018
|16.00-09.00
|-
|Pille
|18.09.2018-19.09.2018
|17:00 - 10.00
|-
|Pille
|18.09.2018
|10:00 - 17.00
|-
|Pille
|17.09.2018-18.09.2018
|15:00 - 10.00
|-
|Ilmar
|17.09.2018
|12:30 - 15.00
|-
|Indrek
|15.09.2018 -17.09.2018
|12:00 - 12.30
|-
|Pille
|14.09.2018-15.09.2018
|9:00 - 11.00
|-
|Kaija
|13.09.2018
|08:00 - 10.00
|-
|Pille
|07.09.2018
|09:00 - 18.00
|-
|Pille
|06.09.2018
|14:00 - 17.00
|-
|Pille
|31.08.2018-01.09.2018
|18:00 - 10.00
|-
|Pille
|30.08.2018-31.08.2018
|17:00 - 15.00
|-
|Pille
|29.08.2018-30.08.2018
|17:00 - 10.00
|-
|Pille
|29.08.2018
|11:00 - 17.00
|-
|Pille
|28.08.2018-29.08.2018
|10:00 - 10.00
|-
|Pille
|27.08.2018
|10:00 - 21.00
|-
|Pille
|24.08.2018
|13:00 - 19.00
|-
|Jelena
|24.08.2018
|9:00 - 13.00
|-
|Pille
|23.08.2018 - 24.08.2018
|17:00 - 09.00
|-
|Fred
|23.08.2018
|10:00 - 13.00
|-
|Pille
|22.08.2018-23.08.2018
|17:00 - 10.00
|-
|Fred
|22.08.2018
|10:00 - 15.00
|-
|Pille
|21.08.2018-22.08.2018
|15:00 - 10.00
|-
|Zane
|20.08.2018
|14:00 - 18.00
|-
|Pille
|19.08.2018-20.08.2018
|18:30 - 12.00
|-
|Pille
|17.08.2018-18.08.2018
|16:30 - 12.00
|-
|Zane
|17.08.2018
|14:00 - 18.00
|-
|Pille
|16.08.2018-17.08.2018
|18:00 - 12.00
|-
|Zane
|16.08.2018
|14:00 - 18.00
|-
|Pille
|16.08.2018
|09:00 - 14.00
|-
|Jelena
|15.08.2018
|11:00 - 19.00
|-
|Fred
|14.08.2018
|10:00 - 17:30
|-
|Jelena
|13.08.2018
|11:00 - 19.00
|-
|Fred
|11.08.2018
|11:00 - 14:30
|-
|Jelena
|10.08.2018
|12:00 - 19:00
|-
|Fred
|9.08.2018
|10:00 - 14:30
|-
|Pille
|8.08.2018
|10:00 - 19:30
|-
|Zane
|7.08.2018
|15:00-19:00
|-
|Fred
|7.08.2018
|10:00 - 14:30
|-
|Fred
|6.08.2018
|17:30 - 19:30
|-
|Pille
|6.08.2018
|09:00 - 17:30
|-
|Fred
|5.08.2018
|11:00 - 14:30
|-
|Fred
|1.08.2018
|10:00 - 14:30
|-
|Fred
|31.07.2018
|11:00 - 14:30
|-
|Fred
|26.07.2018
|11:45 - 18:30
|-
|Pille
|09.07.2018-10.07.2018
|17:00 - 17:00
|-
|Pille
|08.07.2018-09.07.2018
|10:00 - 17:00
|-
|Fred
|1.07.2018
|9:45 - 13:00
|-
|Pille
|30.06.2018-01.07.2018
|10:00 - 09:00
|-
|Pille
|29.06.2018-30.06.2018
|10:00 - 10:00
|-
|Pille
|28.06.2018-29.06.2018
|10:00 - 10:00
|-
|Pille
|27.06.2018-28.06.2018
|10:00 - 10:00
|-
|Fred
|22.03.2018
|12:00 - 17:00
|-
|Kadri
|21.06.2018
|12:00-15:00
|-
|Pille
|20.06.2018-21.06.2018
|17:00 - 12:00
|-
|Fred
|20.06.2018
|12:00 - 17:00
|-
|Pille
|19.06.2018
|10:30 - 11:30
|-
|Kadri
|18.06.2018
|16:00 - 10:30
|-
|Pille
|18.06.2018
|08:00 - 16:00
|-
|Pille
|17.06.2018
|12:00 - 19:00
|-
|Fred
|07.06.2018
|14:00 - 18:00
|-
|Pille
|05.06.2018-06.06.2018
|17:00 - 18:00
|-
|Pille
|01.06.2018-04.06.2018
|17:00 - 18:00
|-
|Alo
|30.05.2018-31.05.2018
|18:00 - 10:00
|-
|Kadri
|28.05.2018-29.05.2018
|14:00 - 9:30
|-
|Pille
|26.05.2018-28.05.2018
|14:00 - 11:00
|-
|Alo
|22.05.2018-23.05.2018
|17:00 - 10:30
|-
|Alo
|21.05.2018-22.05.2018
|17:00 - 10:00
|-
|Pille
|20.05.2018-21.05.2018
|09:00 - 11:00
|-
|Pille
|19.05.2018
|09:00 - 19:00
|-
|Pille
|18.05.2018
|09:00 - 19:00
|-
|Pille
|14.05.2018
|16:00 - 09:00
|-
|Pille (lab session LTTI.00.017)
|09.05.2018
|11:00 - 17:00
|-
|Pille
|07.05.2018
|09:00 - 18:00
|-
|Urmas
|04.05.2018
|09:00 - 16:00
|-
|Urmas
|03.05.2018
|09:00 - 16:00
|-
|Pille (lab session LTTI.00.017)
|02.05.2018
|11:00 - 17:00
|-
|Pille
|28.04.2018
|10:00 - 17:00
|-
|Victor
|27.04.2018
|10:00 - 20:30
|-
|Victor
|26.04.2018
|14:00 - 20:30
|-
|Kadri
|25.04.2018 -26.04.2018
|17:00 - 11:45
|-
|Pille (lab session LTTI.00.017)
|25.04.2018
|11:00 - 17:00
|-
|Victor
|24.04.2018
|09:30 - 20:30
|-
|Victor
|23.04.2018
|09:30 - 20:30
|-
|Victor
|22.04.2018
|09:30 - 20:30
|-
|Pille (lab session LTTI.00.017)
|18.04.2018
|11:00 - 17:00
|-
|Pille
|16.04.2018
|15:00 - 17:00
|-
|Pille
|12.04.2018
|13:00 - 17:00
|-
|Zane
|5.04.2018
|15:00 - 10:00
|-
|Fred
|29.03.2018
|13:13 - 15:00
|-
|Fred
|20.03.2018
|12:00 - 17:00
|-
|Fred
|19.03.2018
|10:00 - 17:00
|-
|Pille
|18.03.2018
|10:00 - 18:00
|-
|Pille
|17.03.2018
|10:00 - 23:59
|-
|Zane
|16.03.2018
|15:00 - 10:00

|-
|Fred
|13.03.2018
|10:00 - 17:00
|-
|Fred
|12.03.2018
|10:00 - 17:00
|-
|Fred
|9.03.2018
|10:00 - 17:00
|-
|Pille
|08.03.2018
|15:00 - 18:00
|-
|Pille
|07.03.2018
|09:00 - 18:00
|-
|Fred
|5.03.2018
|10:00 - 17:00
|-
|Fred
|2.03.2018
|10:00 - 19:45
|-
|Fred
|27.02.2018
|10:00 - 14:36
|-
|Hans
|26.02.2018
|12:15 - 21:00
|-
|Fred
|26.02.2018
|10:00 - 12:00
|-
|Fred
|22.02.2018
|10:00 - 12:00
|-
|Fred
|21.02.2018
|10:00 - 17:00
|-
|Fred
|20.02.2018
|10:00 - 12:00
|-
|Pille
|19.02.2018
|12:30 - 14:30
|-
|Fred
|19.02.2018
|10:00 - 12:30
|-
|Pille
|19.02.2018
|09:00 - 10:00
|-
|Victor
|17.02.2018
|10:00 - 17:00

|-
|Victor
|16.02.2018
|10:00 - 17:00
|-

|Fred
|15.02.2018
|10:00 - 17:00
|-
|Zane
|15.02 - 16.02
|17:00 - 10:00
|-
|Fred
|14.02.2018
|10:00 - 17:00
|-
|Pille
|13.02.2018
|13:00 - 18:00
|-
|Pille
|11.02.-12.02.2018
|10:00 - 10:00
|-
|Pille
|10.02.-11.02.2018
|10:00 - 10:00
|-
|Pille
|09.02.-10.02.2018
|10:00 - 10:00
|-
|Zane
|8.02 - 9.02
|17:00 - 10:00
|-
|Fred
|8.02.2018
|10:00 - 17:00
|-
|Pille
|07.02.2018
|08:00 - 09:30
|-
|Fred
|6.02.2018
|10:00 - 13:00
|-
|Fred
|5.02.2018
|10:00 - 15:00
|-
|Zane
|2.02 - 03.02
|17:00 - 10:00
|-
|Fred
|02.02.2018
|10:00 - 14:00
|-
|Hans
|01.02.2018
|8:00 - 19:00
|-
|Fred
|31.01.2018
|13:00 - 16:30
|-
|Pille
|31.01.2018
|10:30 - 13:00
|-
|Arko
|30.01.2018
|10:00 - 20:00
|-
|Fred
|29.01.2018
|10:00 - 17:00
|-
|Pille
|27.01.2018
|09:00 - 17:00
|-
|Pille
|26.01.2018
|09:00 - 17:00
|-
|Fred
|25.01.2018
|10:00 - 17:00
|-
|Hans
|24.01.2018
|8:00 - 10:00
|-
|Fred
|24.01.2018
|10:00 - 17:00
|-
|Hans
|23.01.2018
|8:00 - 19:00
|-
|Arko
|22.01.2018 - 23.01.2018
|12:00 - 08:00
|-
|Fred
|22.01.2018
|10:00 - 12:00
|-
|Zane
|19.01 - 20.01
|16:00 - 10:00
|-
|Hans
|19.01
|8:00 - 16:00
|-
|Hans
|18.01
|13:00 - 19:00
|-
|Fred
|18.01.2018
|10:00 - 13:00
|-
|Zane
|17.01 - 18.01
|16:00 - 10:00
|-
|Fred
|17.01.2018
|14:00 - 16:00
|-
|Alo
|16.01 - 17.01
|17:00 - 10:00
|-
|Fred
|16.01.2018
|11:00 - 17:00
|-
|Zane
|15.01 - 16.01
|16:00 - 10:00
|-
|Fred
|15.01.2018
|11:00 - 16:00
|-
|Hans
|12.01.2018
|12:00 - 18:00
|-
|Anna-Liisa
|11.01
|10:00 - 12:00
|-
|Fred
|10.01.2018
|11:00 - 17:00
|-
|Alo
|09.01 - 10.01
|17:00 - 10:00
|-
|Anna-Liisa
|09.01
|13:00 - 15:00
|-
|Zane
|08.01 - 09.01
|16:00 - 10:00
|-
|Fred
|08.01.2018
|11:00 - 17:00
|-
|Zane
|05.01 - 06.01
|16:00 - 10:00
|-
|Fred
|05.01.2018
|11:00 - 17:00
|-
|Zane
|04.01 - 05.01
|16:00 - 10:00

|-
|Pille
|02.01.2018
|09:30 - 17:00
|-
|Hans
|29.12.2017
|9:00 - 17:00
|-
|Pille
|27.12.2017
|10:00 - 17:00
|-
|Pille
|22.12.2017
|10:00 - 17:00
|-
|Hans
|21.12.2017
|13:00 - 17:00
|-
|Fred
|21.12.2017
|10:30 - 13:00
|-
|Pille
|19.12.2017
|10:00 - 19:00
|-
|Fred
|18.12.2017
|12:30 - 17:00
|-
|Fred
|15.12.2017
|11:00 - 17:00
|-
|Fred
|14.12.2017
|11:00 - 17:00
|-
|Pille
|13.12.2017
|10:00 - 19:00
|-
|Alo
|12.12 - 13.12.2017
|16:00 - 10:00
|-
|Alo
|11.12 - 12.12.2017
|16:00 - 10:00
|-
|Zane
|7.12 - 8.12.2017
|16:00 - 10:00
|-
|Zane
|6.12 - 7.12.2017
|16:00 - 10:00
|-
|Pille
|08.12.2017
|08:00 - 17:00
|-
|Pille
|04.12.2017
|08:00 - 17:00
|-
|Alo
|24.11 - 25.11.2017
|15:00 - 10:00
|-
|Alo
|23.11 - 24.11.2017
|17:00 - 10:00
|-
|Pille
|23.11.2017
|08:00 - 17:00
|-
|Pille
|21.11.2017
|13:00 - 17:00
|-
|Alo
|9.11 - 10.11.2017
|15:00 - 10:00
|-
|Zane
|7.11 - 8.11.2017
|16:00 - 10:00
|-
|Zane
|1.11 - 2.11.2017
|16:00 - 10:00
|-
|Arko
|30.10 - 31.10.2017
|15:00 - 10:00
|-
|Alo
|24.10 - 25.10.2017
|16:00 - 10:00
|-
|Zane
|17.10 - 18.10.2017
|16:00 - 10:00
|-
|Madis
|10.10 - 10.10.2017
|17:00 - 21:00
|-
|Arko
|06.10 - 07.10.2017
|16:00 - 10:00
|-
|Fred
|06.10.2017
|11:00 - 16:00
|-
|Zane
|05 - 06.10.2017
|16:00 - 10:00
|-
|Fred
|05.10.2017
|10:00 - 16:00
|-
|Arko
|04 - 05.10.2017
|15:00 - 10:00
|-
|Fred
|02.10.2017
|10:30-17:00
|-
|Pille
|19.09.2017
|09:00-18:00
|-
|Pille
|14.09.2017
|09:00-20:00
|-
|Pille
|11.09.2017
|10:00-18:30
|-
|Pille
|06.09.2017
|14:30-18:30
|-
|Fred
|04.09.2017
|10:30-13:30
|-
|Pille
|22.08.2017
|09:00-20:30
|-
|Pille
|21.08.2017
|10:00-20:30
|-
|Pille
|16.08.2017
|10:00-20:30
|-
|Pille
|15.08.2017
|12:00-20:30
|-
|Pille
|14.08.2017
|12:00-20:30
|-
|Pille
|10.08.2017
|10:00-20:30
|-
|Pille
|09.08.2017
|14:00-20:30
|-
|Pille
|08.08.2017
|10:00-20:30
|-
|Pille
|07.08.2017
|10:00-20:30
|-
|Pille
|04.08.2017
|10:00-15:30
|-
|Pille
|31.07.2017
|10:00-20:00
|-
|Pille
|28.07.2017
|08:30-20:00
|-
|Pille
|27.07.2017
|09:30-20:00
|-
|Pille
|25.07.2017
|08:30-21:00
|-
|Fred
|21.07.2017
|9:30-15:30
|-
|Fred
|20.07.2017
|9:30-21:30
|-
|Fred
|19.07.2017
|9:30-21:30
|-
|Pille
|18.07.2017
|08:30-21:00
|-
|Fred
|17.07.2017
|9:30-21:30
|-
|Fred
|14.07.2017
|10:30-19:30
|-
|Pille
|13.07.2017
|08:30-21:00
|-
|Fred
|12.07.2017
|10:30-19:30
|-
|Fred
|11.07.2017
|10:30-17:30
|-
|Pille
|10.07.2017
|08:30-15:30
|-
|Fred
|06.07.2017
|10:30-14:30
|-
|Fred
|5.07.2017
|10:30-17:30
|-
|Pille
|05.07.2017
|09:00-10:30
|-
|Fred
|4.07.2017
|10:30-17:30
|-
|Pille
|04.07.2017
|08:30-10:30
|-
|Fred
|3.07.2017
|10:30-17:30
|-
|Fred
|28.06.2017
|10:30-16:30
|-
|Pille
|14.06.2017
|09:00-17:30
|-
|Fred
|13.06.2017
|10:30-16:30
|-
|Pille
|12.06.2017
|09:30-17:30
|-
|Fred
|08.06.2017
|10:30-16:30
|-
|Fred
|06.06.2017
|10:30-16:30
|-
|Pille
|06.06.2017
|09:30-10:30
|-
|Pille
|05.06.2017
|13:00-15:00
|-
|Pille
|02.06.2017
|11:30-16:30
|-
|Fred
|01.06.2017
|10:30-12:30
|-
|Inga
|24.05.2017
|16:30-17:30
|-
|Fred
|24.05.2017
|11:00-16:30
|-
|Zane
|17.05. - 18.05.2017
|16:00-10:00
|-
|Arko
|18.05. - 19.05.2017
|16:00-10:00
|-
|Arko
|15.05. - 16.05.2017
|16:00-10:00
|-
|Kadi-Anne
|11.05.2017
|11:00-16:30
|-
||Zane
|09.05.2017 - 10.05.2017
|16:00 - 10:00
|-
|Pille
|09.05.2017
|09:00-18:00
|-
||Zane
|08.05.2017 - 09.05.2017
|16:00 - 9:00
|-
|Kadi-Anne
|08.05.2017
|11:00-15:00
|-
|Pille
|08.05.2017
|08:00-10:00
|-
|Pille
|04.05.2017
|11:00-17:00
|-
||Zane
|03.05.2017 - 04.05.2017
|17:00 - 11:00
|-
|Pille
|03.05.2017
|10:30-17:00
|-
||Arko
|02.05 - 03.05
|16:00-10:30
|-
||Pille
|28.04.2017
|16:00-18:30
|-
||Pille
|28.04.2017
|11:00-13:00
|-
||Pille
|27.04.2017
|10:00-17:00
|-
||Pille
|26.04.2017
|17:00-18:00
|-
||Pille
|20.04.2017
|10:00-15:00
|-
||Zane
|19.04.2017 - 20.04.2017
|15:00 - 10:00
|-
||Pille
|19.04.2017
|09:00-14:00
|-
||Pille
|18.04.2017
|10:00-18:00
|-
||Arko
|17.04 - 18.04.2017
|16:00 - 10:00
|-
||Pille
|13.04.2017
|09:00-17:00
|-
||Pille
|12.04.2017
|09:00-10:00
|-
||Pille
|11.04.2017
|15:00-17:30
|-
||Zane
|07.04.2017
|9:00 - 12:00
|-
||Zane
|06.04.2017-07.04.2017
|15:30 - 9:00
|-
||Pille
|06.04.2017
|14:00 - 15:30
|-
||Pille
|05.04.2017
|14:00 - 18:00
|-
||Arko
|04.04.2017
|09:00 - 16:00
|-
||Fred
|04.04.2017
|16:00 - 11:00
|-
||Fred
|27.03.2017
|20:00 - 11:00
|-
||Pille
|22.03.2017
|11:00 - 17:00
|-
||Arko
|20.03.2017
|09:00 - 17:00
|-
||Pille
|17.03.2017
|11:00-17:00
|-
||Zane
|16.03.2017
|19:00 - 10:00
|-
||Pille
|16.03.2017
|14:00-18:00
|-
||Zane
|15.03.2017
|18:00 - 10:00
|-
||Pille
|15.03.2017
|08:30-17:00
|-
||Pille
|14.03.2017
|12:00-17:00
|-
||Zane
|10.03.2017
|16:00 - 10:00
|-
||Kadi-Anne
|09.03.2017
|16:30-17:30
|-
||Pille
|09.03.2017
|09:00-15:00
|-
||Pille
|06.03.2017
|11:00-13:00
|-
||Kadi-Anne
|02.03.2017
|13:00-16:00
|-
||Pille
|02.03.2017
|09:00-12:00
|-
||Pille
|01.03.2017
|14:00-17:00
|-
||Pille
|28.02.2017
|10:00-16:00
|-
||Pille
|27.02.2017
|10:00-18:00
|-
||Pille
|23.02.2017
|09:00-14:00
|-
||Pille
|22.02.2017
|16:00-19:00
|-
||Pille
|21.02.2017
|15:30-17:00
|-
||Pille
|16.02.2017
|14:30-17:00
|-
||Pille
|15.02.2017
|09:00-18:00
|-
||Alo
|14.02.2017 - 15.02.2017
|18:00-09:00
|-
||Pille
|8.02.2017
|09:00-15:00
|-
||Pille
|7.02.2017
|15:00-18:00
|-
||Madis
|06.02.2017 - 07.02.2017
|21:00-11:00
|-
||Pille
|1.02.2017
|12:00-17:30
|-
||Madis
|31.01.2017 - 01.02.2017
|20:00-10:00
|-
||Pille
|31.01.2017
|10:00-17:30
|-
||Pille
|30.01.2017
|13:00-15:30
|-
||Fred
|25.01.2017
|00:00-11:00
|-
||Pille
|24.01.2017
|10:00-17:00
|-
||Pille
|23.01.2017
|13:00-17:00
|-
||Fred
|23.01.2017
|12:00-13:00
|-
||Pille
|19.01.2017
|10:00-12:00
|-
||Pille
|18.01.2017
|13:00-17:00
|-
||Pille
|13.12
|10:00-15:00
|-
||Pille
|12.12
|10:00-15:00
|-
||Pille
|09.12
|13:00-17:00
|-
||Pille
|07.12
|13:00-17:00
|-
||Pille
|06.12
|13:00-15:00
|-
||Madis
|05.12-06.12
|14:00-10:00
|-
||Pille
|30.11
|13:00-17:00
|-
||Pille
|29.11
|16:00-17:00
|-
||Zane
|29.11 - 30.11.2016
|17:00-10:00
|-
||Kadi-Anne
|14.11 - 15.11.2016
|12:00-12:00
|-
||Kadi-Anne
|10.11 - 11.11.2016
|11:00-12:00
|-
||Kadi-Anne
|03.11 - 04.11.2016
|12:00-12:00
|-
||Kadi-Anne
|02.11 - 03.11.2016
|14:00-12:00
|-
||Kadi-Anne
|19.10 - 20.10.2016
|10:00-13:00
|-
||Kadi-Anne
|05.10 - 06.10.2016
|13:00-12:00
|-
|Kadi-Anne
|26.09 - 27.09.2016
|15:00-12:00
|-
|Georg
|22.09 - 23.09.2016
|15:00-10:00
|-
|Georg
|20.09 - 21.09.2016
|15:00-10:00
|-
|Anna-Liisa
|06.09.2016
|10:00-12:00
|-
|Kaur
|1.09.2016
|8:00-17:00
|-
|Kaur
|31.08.2016
|10:00-18:00
|-
|Anna-Liisa
|30.08.2016
|10:00-18:00
|-
|Anna-Liisa
|29.08.2016
|10:00-18:00
|-
|Anna-Liisa
|12.08.2016
|10:00-17:00
|-
|Anna-Liisa
|10.08.2016
|16:00-17:00
|-
|Anna-Liisa
|30.06.2016
|11:30-14:00
|-
|Carla
|16.05.2016
|10.00-16.00
|-
|Andreas
|11.05.2016
|15:00-17:00
|-
|Hans
|10.05-10.05.2016
|11.00-16.00
|-
|Georg
|10.05-11.05.2016
|16.00-10.00
|-
|Georg
|09.05-10.05.2016
|16.00-10.00
|-
|Arko
|09.05.2016
|10.00-14.00
|-
|Friedrich
|06.05.2016
|10.00-14.00
|-
|Tarmo
|03.05.2016
|14.00-17.00
|-
|Carla
|29.04.2016
|10.00-16.00
|-
|Arko
|25.04.2016
|14.00-17.00
|-
|Alo
|18.04-19.04.2016
|17.00-10.00
|-
|Alo
|15.04-16.04.2016
|16.00-10.00
|-
|Alo
|14.04.2016
|14.00-19.00
|-
|Carla
|14.04.2016
|10.00-14.00
|-
|Alo
|13.04.2016
|12.00-17.00
|-
|Alo
|07.04.2016
|13.00-18.00
|-
|Alo
|06.04.2016
|10.00-19.00
|-
|Alo
|05.04.2016
|10.00-19.00
|-
|Arko & Anna
|04.04 - 05.04.2016
|16.00-10.00
|-
|Alo
|04.04.2016
|11.00-12.00
|-
|Alo
|01.04.2016
|11.00-17.00
|-
|Alo
|24.03.2016
|14.00-19.00
|-
|Alo
|22.03.2016
|14.00-20.00
|-
|Alo
|10.03.2016
|14.00-20.00
|-
|Alo
|09.03.2016
|15.00-20.00
|-
|Alo
|08.03.2016
|14.00-15.30
|-
|Paul
|04.03.2016 - 05.03
|16.00-16.00
|-
|Alo
|03.03.2016-04.03.2016
|13.00-10.00
|-
|Anna-Liisa
|03.03.2016
|9:30-12:00
|-
|Anna-Liisa
|02.03.2016
|15.00-17.00
|-
|Alo
|01.03.2016-02.03.2016
|16.00-10.00
|-
|Anna-Liisa
|26.02.2016
|15.00-17.00
|-
|Georg
|23.02.2016-24.02.2016
|16.00-10.00
|-
|Arko
|22.02.2016
|12.00-17.00
|-
|Anna-Liisa
|18.02.2016
|9.00-16.00
|-
|Anna-Liisa
|15.02.2016
|13.00-16.00
|-
|Georg
|03.02.2016-04.02.2016
|16.00-10.00
|-
|Zane
|19.01.2016 - 20.01.2016
|16.00-10.00
|-
|Paul
|18.01.2015 - 19.01
|16.00-10.00
|-
|Alo/Zane
|15.01.2015 - 16.01.2016
|16.00-10.00
|-
|Anna-Liisa
|11.01.2015
|14.40-17.00
|-
|Anna-Liisa
|08.01.2015
|14.00-17.00
|-
|Alo/Zane
|07.01.2015
|13.00-17.00
|-
|Alo/Zane
|05.01.2015
|10.00-18.00
|-
|Arko
|04.01 - 05.01.2016
|16.00-10.00
|-
|Anna-Liisa
|28.12.2015
|12.00-14.00
|-
|Alo/Zane
|14.12.2015
|14.00-19.00
|-
|Alo
|07.12.2015-08.12.2015
|17.00 - 10.00
|-
|Madis
|06.12.2015-07.12.2015
|19.00 - 9.00
|-
|Alo/Zane
|02.12.2015
|13.00-17.00
|-
|Alo
|01.12.2015
|14.00-17.00
|-
|Alo
|30.11.2015
|14.00-16.00
|-
|Alo
|26.11.2015
|13.00-16.00
|-
|Anna-Liisa
|26.11.2015
|11.00-13.00
|-
|Alo
|25.11.2015
|13.00-16.00
|-
|Alo
|24.11.2015-25.11.2015
|16.00-10.00
|-
|Georg
|23.11.2015-24.11.2015
|16.00-10.00
|-
|Alo/Arko
|20.11.2015-21.11.2015
|16.00 - 10.00
|-
|Alo/Arko
|19.11.2015-20.11.2015
|16.00 - 10.00
|-
|Paul
|18.11.2015-19.11.2015
|16.00 - 10.00
|-
|Anna-Liisa
|18.11.2015
|11.00-16.00
|-
|Pejman/Arko
|17.11.2015-18.11.2015
|16.00-10.00
|-
|Alo
|16.11.2015-17.11.2015
|15.00-10.00
|-
|Anna-Liisa
|13.11.2015
|14.00-18.00
|-
|Fred
|11.11.2015
|10.00-17.00
|-
|Arko
|10.-11.11.2015
|16.00-10.00
|-
|Pejman/Arko
|06.10.2015-
|10.00-18.00
|-
|Fred
|04.11.2015
|10.30-17.00
|-
|Anna-Liisa
|21.10.2015
|9.00-16.00
|-
|Anna-Liisa
|20.10.2015
|10.30-14.00
|-
|Georg/Paul
|14.10.2015-15.10.2015
|17.00-10.00
|-
|-
|Alo
|14.10.2015
|10.00-17.00
|-
|-
|Paul/Georg
|13.10.2015-14.10.2015
|12.00-12.00
|-
|Fred
|30.09.2015
|10:00-18:00
|-
|Kaur
|24.09.2015
|11:00-17:00
|-
|Hans
|15.09.2015 - 16.09.2015
|10:00-15:00
|-
|Hans
|08.09.2015 - 10.09.2015
|15:00-21:00
|-
|Hans
|01.09.2015 - 02.09.2015
|15:00-21:00
|-
|Friedrich
|17.08.2015-18.08.2015
|10.00-17.00
|-
|Paul
|02.07.2015-03.07.2015
|15.00-19.00
|-
|Zane
|29.06 - 30.06
|17:30-10:00
|-
|Zane
|05.06 - 06.06
|17:30-11:30
|-
|Hans
|04.06 - 06.06
|12:45-10:00
|-
|Zane
|03.06 - 04.06
|21:00-10:00
|-
|Inga
|02.06
|15:00-18:00
|-
|Arko
|26.05-27.05
|17:00-10:00
|-
|Zane
|18.05-19.05
|16:00-10:00
|-
|Zane
|14.05-15.05
|16:00-10:00
|-
|Rudolf
|12.05
|14:00-17:00
|-
|Zane
|11.05
|14:00-15:00
|-
|Arko
|11.05 - 12.05.2015
|16:00 - 10:00
|-
|Arko
|07.05 - 08.05.2015
|17:00 - 10:00
|-
|Anna-Liisa
|07.05.2015
|9.30 - 13.00
|-
|Kätlin
|06.05.2015
|11.00 - 00.00
|-
|Anna-Liisa
|30.04.2015
|10.00 - 13.00
|-
|Arko
|24.04.2015 - 24.04.2015
|11.00 - 19.00
|-
|Kätlin
|22.04.2015 - 23.04.2015
|13.00 - 10.00
|-
|Anna-Liisa
|16.04.2015
|10:00 - 11:00
|-
|Inga
|26.03.2015
|12:30 - 17:00
|-
|Inna & Friedrich
|26.03.2015
|10:00 - 12:00
|-
|Arko
|25.03.2015-27.03.2015
|12:00 - 19:00
|-
|Paul
|09.03.2015-10.03.2015
|15.00-12.00 (10.03.2015)
|-
|Anna-Liisa
|09.03.2015
|09:00-12:00
|-
|Inga
|02.03.2015
|12:00-17:00
|-
|Arko
|23.02.2015 - 27.02.2015
|va Anna-Liisa aeg
|-
|Anna-Liisa
|25.02.2015
|9:00-12:00
|-
|Friedrich
|16.02.2015 - 20.02.2015
| 00-24
|-
|Rauno
|07.01.2015 18:00 - 08.01.2015 19:00
|-
|----
|-
|Kätlin
|25.09.2014
|16:00-24.00
|-
|Madis
|06.10.2014
|12:00-14:00
|-
|Rudolf
|06.10.2014
|14:00-17:00
|-
|Kätlin
|16.10.2014
|15:00-24.00
|-
|Paul
|17.11.2014
|13:00-24:00
|-
|Madis
|18.11.2014
|13:00-24:00
|-
|Madis
|19.11.2014
|09:00-22:00
|-
|Kätlin
|20.11.2014
|11:00-24:00
|-
|Anna-Liisa
|21.11.2014
|13:00-15:00
|-
|Kätlin
|03.12.2014
|10:00-24:00
|-
|Kätlin
|04.12.2014
|10:00-24:00
|-
|Kätlin
|05.12.2014
|00:00-24:00
|-
|-
|Arko
|17.12.2014
|12:00-24:00
|-
|Madis
|18.12.2014
|12:00-24:00

Potentiostat booking (PARstat)

2018-09-10T07:33:47Z

Gajanee: /* Booking list */

=='''Booking list'''==

'''NB! Newer bookings on top!''' 

{| class="wikitable"
!colspan="6"|Booking list
|-
|Kaija
|13.09.2018
|08:00 - 10.00
|-
|Pille
|07.09.2018
|09:00 - 18.00
|-
|Pille
|06.09.2018
|14:00 - 17.00
|-
|Pille
|31.08.2018-01.09.2018
|18:00 - 10.00
|-
|Pille
|30.08.2018-31.08.2018
|17:00 - 15.00
|-
|Pille
|29.08.2018-30.08.2018
|17:00 - 10.00
|-
|Pille
|29.08.2018
|11:00 - 17.00
|-
|Pille
|28.08.2018-29.08.2018
|10:00 - 10.00
|-
|Pille
|27.08.2018
|10:00 - 21.00
|-
|Pille
|24.08.2018
|13:00 - 19.00
|-
|Jelena
|24.08.2018
|9:00 - 13.00
|-
|Pille
|23.08.2018 - 24.08.2018
|17:00 - 09.00
|-
|Fred
|23.08.2018
|10:00 - 13.00
|-
|Pille
|22.08.2018-23.08.2018
|17:00 - 10.00
|-
|Fred
|22.08.2018
|10:00 - 15.00
|-
|Pille
|21.08.2018-22.08.2018
|15:00 - 10.00
|-
|Zane
|20.08.2018
|14:00 - 18.00
|-
|Pille
|19.08.2018-20.08.2018
|18:30 - 12.00
|-
|Pille
|17.08.2018-18.08.2018
|16:30 - 12.00
|-
|Zane
|17.08.2018
|14:00 - 18.00
|-
|Pille
|16.08.2018-17.08.2018
|18:00 - 12.00
|-
|Zane
|16.08.2018
|14:00 - 18.00
|-
|Pille
|16.08.2018
|09:00 - 14.00
|-
|Jelena
|15.08.2018
|11:00 - 19.00
|-
|Fred
|14.08.2018
|10:00 - 17:30
|-
|Jelena
|13.08.2018
|11:00 - 19.00
|-
|Fred
|11.08.2018
|11:00 - 14:30
|-
|Jelena
|10.08.2018
|12:00 - 19:00
|-
|Fred
|9.08.2018
|10:00 - 14:30
|-
|Pille
|8.08.2018
|10:00 - 19:30
|-
|Zane
|7.08.2018
|15:00-19:00
|-
|Fred
|7.08.2018
|10:00 - 14:30
|-
|Fred
|6.08.2018
|17:30 - 19:30
|-
|Pille
|6.08.2018
|09:00 - 17:30
|-
|Fred
|5.08.2018
|11:00 - 14:30
|-
|Fred
|1.08.2018
|10:00 - 14:30
|-
|Fred
|31.07.2018
|11:00 - 14:30
|-
|Fred
|26.07.2018
|11:45 - 18:30
|-
|Pille
|09.07.2018-10.07.2018
|17:00 - 17:00
|-
|Pille
|08.07.2018-09.07.2018
|10:00 - 17:00
|-
|Fred
|1.07.2018
|9:45 - 13:00
|-
|Pille
|30.06.2018-01.07.2018
|10:00 - 09:00
|-
|Pille
|29.06.2018-30.06.2018
|10:00 - 10:00
|-
|Pille
|28.06.2018-29.06.2018
|10:00 - 10:00
|-
|Pille
|27.06.2018-28.06.2018
|10:00 - 10:00
|-
|Fred
|22.03.2018
|12:00 - 17:00
|-
|Kadri
|21.06.2018
|12:00-15:00
|-
|Pille
|20.06.2018-21.06.2018
|17:00 - 12:00
|-
|Fred
|20.06.2018
|12:00 - 17:00
|-
|Pille
|19.06.2018
|10:30 - 11:30
|-
|Kadri
|18.06.2018
|16:00 - 10:30
|-
|Pille
|18.06.2018
|08:00 - 16:00
|-
|Pille
|17.06.2018
|12:00 - 19:00
|-
|Fred
|07.06.2018
|14:00 - 18:00
|-
|Pille
|05.06.2018-06.06.2018
|17:00 - 18:00
|-
|Pille
|01.06.2018-04.06.2018
|17:00 - 18:00
|-
|Alo
|30.05.2018-31.05.2018
|18:00 - 10:00
|-
|Kadri
|28.05.2018-29.05.2018
|14:00 - 9:30
|-
|Pille
|26.05.2018-28.05.2018
|14:00 - 11:00
|-
|Alo
|22.05.2018-23.05.2018
|17:00 - 10:30
|-
|Alo
|21.05.2018-22.05.2018
|17:00 - 10:00
|-
|Pille
|20.05.2018-21.05.2018
|09:00 - 11:00
|-
|Pille
|19.05.2018
|09:00 - 19:00
|-
|Pille
|18.05.2018
|09:00 - 19:00
|-
|Pille
|14.05.2018
|16:00 - 09:00
|-
|Pille (lab session LTTI.00.017)
|09.05.2018
|11:00 - 17:00
|-
|Pille
|07.05.2018
|09:00 - 18:00
|-
|Urmas
|04.05.2018
|09:00 - 16:00
|-
|Urmas
|03.05.2018
|09:00 - 16:00
|-
|Pille (lab session LTTI.00.017)
|02.05.2018
|11:00 - 17:00
|-
|Pille
|28.04.2018
|10:00 - 17:00
|-
|Victor
|27.04.2018
|10:00 - 20:30
|-
|Victor
|26.04.2018
|14:00 - 20:30
|-
|Kadri
|25.04.2018 -26.04.2018
|17:00 - 11:45
|-
|Pille (lab session LTTI.00.017)
|25.04.2018
|11:00 - 17:00
|-
|Victor
|24.04.2018
|09:30 - 20:30
|-
|Victor
|23.04.2018
|09:30 - 20:30
|-
|Victor
|22.04.2018
|09:30 - 20:30
|-
|Pille (lab session LTTI.00.017)
|18.04.2018
|11:00 - 17:00
|-
|Pille
|16.04.2018
|15:00 - 17:00
|-
|Pille
|12.04.2018
|13:00 - 17:00
|-
|Zane
|5.04.2018
|15:00 - 10:00
|-
|Fred
|29.03.2018
|13:13 - 15:00
|-
|Fred
|20.03.2018
|12:00 - 17:00
|-
|Fred
|19.03.2018
|10:00 - 17:00
|-
|Pille
|18.03.2018
|10:00 - 18:00
|-
|Pille
|17.03.2018
|10:00 - 23:59
|-
|Zane
|16.03.2018
|15:00 - 10:00

|-
|Fred
|13.03.2018
|10:00 - 17:00
|-
|Fred
|12.03.2018
|10:00 - 17:00
|-
|Fred
|9.03.2018
|10:00 - 17:00
|-
|Pille
|08.03.2018
|15:00 - 18:00
|-
|Pille
|07.03.2018
|09:00 - 18:00
|-
|Fred
|5.03.2018
|10:00 - 17:00
|-
|Fred
|2.03.2018
|10:00 - 19:45
|-
|Fred
|27.02.2018
|10:00 - 14:36
|-
|Hans
|26.02.2018
|12:15 - 21:00
|-
|Fred
|26.02.2018
|10:00 - 12:00
|-
|Fred
|22.02.2018
|10:00 - 12:00
|-
|Fred
|21.02.2018
|10:00 - 17:00
|-
|Fred
|20.02.2018
|10:00 - 12:00
|-
|Pille
|19.02.2018
|12:30 - 14:30
|-
|Fred
|19.02.2018
|10:00 - 12:30
|-
|Pille
|19.02.2018
|09:00 - 10:00
|-
|Victor
|17.02.2018
|10:00 - 17:00

|-
|Victor
|16.02.2018
|10:00 - 17:00
|-

|Fred
|15.02.2018
|10:00 - 17:00
|-
|Zane
|15.02 - 16.02
|17:00 - 10:00
|-
|Fred
|14.02.2018
|10:00 - 17:00
|-
|Pille
|13.02.2018
|13:00 - 18:00
|-
|Pille
|11.02.-12.02.2018
|10:00 - 10:00
|-
|Pille
|10.02.-11.02.2018
|10:00 - 10:00
|-
|Pille
|09.02.-10.02.2018
|10:00 - 10:00
|-
|Zane
|8.02 - 9.02
|17:00 - 10:00
|-
|Fred
|8.02.2018
|10:00 - 17:00
|-
|Pille
|07.02.2018
|08:00 - 09:30
|-
|Fred
|6.02.2018
|10:00 - 13:00
|-
|Fred
|5.02.2018
|10:00 - 15:00
|-
|Zane
|2.02 - 03.02
|17:00 - 10:00
|-
|Fred
|02.02.2018
|10:00 - 14:00
|-
|Hans
|01.02.2018
|8:00 - 19:00
|-
|Fred
|31.01.2018
|13:00 - 16:30
|-
|Pille
|31.01.2018
|10:30 - 13:00
|-
|Arko
|30.01.2018
|10:00 - 20:00
|-
|Fred
|29.01.2018
|10:00 - 17:00
|-
|Pille
|27.01.2018
|09:00 - 17:00
|-
|Pille
|26.01.2018
|09:00 - 17:00
|-
|Fred
|25.01.2018
|10:00 - 17:00
|-
|Hans
|24.01.2018
|8:00 - 10:00
|-
|Fred
|24.01.2018
|10:00 - 17:00
|-
|Hans
|23.01.2018
|8:00 - 19:00
|-
|Arko
|22.01.2018 - 23.01.2018
|12:00 - 08:00
|-
|Fred
|22.01.2018
|10:00 - 12:00
|-
|Zane
|19.01 - 20.01
|16:00 - 10:00
|-
|Hans
|19.01
|8:00 - 16:00
|-
|Hans
|18.01
|13:00 - 19:00
|-
|Fred
|18.01.2018
|10:00 - 13:00
|-
|Zane
|17.01 - 18.01
|16:00 - 10:00
|-
|Fred
|17.01.2018
|14:00 - 16:00
|-
|Alo
|16.01 - 17.01
|17:00 - 10:00
|-
|Fred
|16.01.2018
|11:00 - 17:00
|-
|Zane
|15.01 - 16.01
|16:00 - 10:00
|-
|Fred
|15.01.2018
|11:00 - 16:00
|-
|Hans
|12.01.2018
|12:00 - 18:00
|-
|Anna-Liisa
|11.01
|10:00 - 12:00
|-
|Fred
|10.01.2018
|11:00 - 17:00
|-
|Alo
|09.01 - 10.01
|17:00 - 10:00
|-
|Anna-Liisa
|09.01
|13:00 - 15:00
|-
|Zane
|08.01 - 09.01
|16:00 - 10:00
|-
|Fred
|08.01.2018
|11:00 - 17:00
|-
|Zane
|05.01 - 06.01
|16:00 - 10:00
|-
|Fred
|05.01.2018
|11:00 - 17:00
|-
|Zane
|04.01 - 05.01
|16:00 - 10:00

|-
|Pille
|02.01.2018
|09:30 - 17:00
|-
|Hans
|29.12.2017
|9:00 - 17:00
|-
|Pille
|27.12.2017
|10:00 - 17:00
|-
|Pille
|22.12.2017
|10:00 - 17:00
|-
|Hans
|21.12.2017
|13:00 - 17:00
|-
|Fred
|21.12.2017
|10:30 - 13:00
|-
|Pille
|19.12.2017
|10:00 - 19:00
|-
|Fred
|18.12.2017
|12:30 - 17:00
|-
|Fred
|15.12.2017
|11:00 - 17:00
|-
|Fred
|14.12.2017
|11:00 - 17:00
|-
|Pille
|13.12.2017
|10:00 - 19:00
|-
|Alo
|12.12 - 13.12.2017
|16:00 - 10:00
|-
|Alo
|11.12 - 12.12.2017
|16:00 - 10:00
|-
|Zane
|7.12 - 8.12.2017
|16:00 - 10:00
|-
|Zane
|6.12 - 7.12.2017
|16:00 - 10:00
|-
|Pille
|08.12.2017
|08:00 - 17:00
|-
|Pille
|04.12.2017
|08:00 - 17:00
|-
|Alo
|24.11 - 25.11.2017
|15:00 - 10:00
|-
|Alo
|23.11 - 24.11.2017
|17:00 - 10:00
|-
|Pille
|23.11.2017
|08:00 - 17:00
|-
|Pille
|21.11.2017
|13:00 - 17:00
|-
|Alo
|9.11 - 10.11.2017
|15:00 - 10:00
|-
|Zane
|7.11 - 8.11.2017
|16:00 - 10:00
|-
|Zane
|1.11 - 2.11.2017
|16:00 - 10:00
|-
|Arko
|30.10 - 31.10.2017
|15:00 - 10:00
|-
|Alo
|24.10 - 25.10.2017
|16:00 - 10:00
|-
|Zane
|17.10 - 18.10.2017
|16:00 - 10:00
|-
|Madis
|10.10 - 10.10.2017
|17:00 - 21:00
|-
|Arko
|06.10 - 07.10.2017
|16:00 - 10:00
|-
|Fred
|06.10.2017
|11:00 - 16:00
|-
|Zane
|05 - 06.10.2017
|16:00 - 10:00
|-
|Fred
|05.10.2017
|10:00 - 16:00
|-
|Arko
|04 - 05.10.2017
|15:00 - 10:00
|-
|Fred
|02.10.2017
|10:30-17:00
|-
|Pille
|19.09.2017
|09:00-18:00
|-
|Pille
|14.09.2017
|09:00-20:00
|-
|Pille
|11.09.2017
|10:00-18:30
|-
|Pille
|06.09.2017
|14:30-18:30
|-
|Fred
|04.09.2017
|10:30-13:30
|-
|Pille
|22.08.2017
|09:00-20:30
|-
|Pille
|21.08.2017
|10:00-20:30
|-
|Pille
|16.08.2017
|10:00-20:30
|-
|Pille
|15.08.2017
|12:00-20:30
|-
|Pille
|14.08.2017
|12:00-20:30
|-
|Pille
|10.08.2017
|10:00-20:30
|-
|Pille
|09.08.2017
|14:00-20:30
|-
|Pille
|08.08.2017
|10:00-20:30
|-
|Pille
|07.08.2017
|10:00-20:30
|-
|Pille
|04.08.2017
|10:00-15:30
|-
|Pille
|31.07.2017
|10:00-20:00
|-
|Pille
|28.07.2017
|08:30-20:00
|-
|Pille
|27.07.2017
|09:30-20:00
|-
|Pille
|25.07.2017
|08:30-21:00
|-
|Fred
|21.07.2017
|9:30-15:30
|-
|Fred
|20.07.2017
|9:30-21:30
|-
|Fred
|19.07.2017
|9:30-21:30
|-
|Pille
|18.07.2017
|08:30-21:00
|-
|Fred
|17.07.2017
|9:30-21:30
|-
|Fred
|14.07.2017
|10:30-19:30
|-
|Pille
|13.07.2017
|08:30-21:00
|-
|Fred
|12.07.2017
|10:30-19:30
|-
|Fred
|11.07.2017
|10:30-17:30
|-
|Pille
|10.07.2017
|08:30-15:30
|-
|Fred
|06.07.2017
|10:30-14:30
|-
|Fred
|5.07.2017
|10:30-17:30
|-
|Pille
|05.07.2017
|09:00-10:30
|-
|Fred
|4.07.2017
|10:30-17:30
|-
|Pille
|04.07.2017
|08:30-10:30
|-
|Fred
|3.07.2017
|10:30-17:30
|-
|Fred
|28.06.2017
|10:30-16:30
|-
|Pille
|14.06.2017
|09:00-17:30
|-
|Fred
|13.06.2017
|10:30-16:30
|-
|Pille
|12.06.2017
|09:30-17:30
|-
|Fred
|08.06.2017
|10:30-16:30
|-
|Fred
|06.06.2017
|10:30-16:30
|-
|Pille
|06.06.2017
|09:30-10:30
|-
|Pille
|05.06.2017
|13:00-15:00
|-
|Pille
|02.06.2017
|11:30-16:30
|-
|Fred
|01.06.2017
|10:30-12:30
|-
|Inga
|24.05.2017
|16:30-17:30
|-
|Fred
|24.05.2017
|11:00-16:30
|-
|Zane
|17.05. - 18.05.2017
|16:00-10:00
|-
|Arko
|18.05. - 19.05.2017
|16:00-10:00
|-
|Arko
|15.05. - 16.05.2017
|16:00-10:00
|-
|Kadi-Anne
|11.05.2017
|11:00-16:30
|-
||Zane
|09.05.2017 - 10.05.2017
|16:00 - 10:00
|-
|Pille
|09.05.2017
|09:00-18:00
|-
||Zane
|08.05.2017 - 09.05.2017
|16:00 - 9:00
|-
|Kadi-Anne
|08.05.2017
|11:00-15:00
|-
|Pille
|08.05.2017
|08:00-10:00
|-
|Pille
|04.05.2017
|11:00-17:00
|-
||Zane
|03.05.2017 - 04.05.2017
|17:00 - 11:00
|-
|Pille
|03.05.2017
|10:30-17:00
|-
||Arko
|02.05 - 03.05
|16:00-10:30
|-
||Pille
|28.04.2017
|16:00-18:30
|-
||Pille
|28.04.2017
|11:00-13:00
|-
||Pille
|27.04.2017
|10:00-17:00
|-
||Pille
|26.04.2017
|17:00-18:00
|-
||Pille
|20.04.2017
|10:00-15:00
|-
||Zane
|19.04.2017 - 20.04.2017
|15:00 - 10:00
|-
||Pille
|19.04.2017
|09:00-14:00
|-
||Pille
|18.04.2017
|10:00-18:00
|-
||Arko
|17.04 - 18.04.2017
|16:00 - 10:00
|-
||Pille
|13.04.2017
|09:00-17:00
|-
||Pille
|12.04.2017
|09:00-10:00
|-
||Pille
|11.04.2017
|15:00-17:30
|-
||Zane
|07.04.2017
|9:00 - 12:00
|-
||Zane
|06.04.2017-07.04.2017
|15:30 - 9:00
|-
||Pille
|06.04.2017
|14:00 - 15:30
|-
||Pille
|05.04.2017
|14:00 - 18:00
|-
||Arko
|04.04.2017
|09:00 - 16:00
|-
||Fred
|04.04.2017
|16:00 - 11:00
|-
||Fred
|27.03.2017
|20:00 - 11:00
|-
||Pille
|22.03.2017
|11:00 - 17:00
|-
||Arko
|20.03.2017
|09:00 - 17:00
|-
||Pille
|17.03.2017
|11:00-17:00
|-
||Zane
|16.03.2017
|19:00 - 10:00
|-
||Pille
|16.03.2017
|14:00-18:00
|-
||Zane
|15.03.2017
|18:00 - 10:00
|-
||Pille
|15.03.2017
|08:30-17:00
|-
||Pille
|14.03.2017
|12:00-17:00
|-
||Zane
|10.03.2017
|16:00 - 10:00
|-
||Kadi-Anne
|09.03.2017
|16:30-17:30
|-
||Pille
|09.03.2017
|09:00-15:00
|-
||Pille
|06.03.2017
|11:00-13:00
|-
||Kadi-Anne
|02.03.2017
|13:00-16:00
|-
||Pille
|02.03.2017
|09:00-12:00
|-
||Pille
|01.03.2017
|14:00-17:00
|-
||Pille
|28.02.2017
|10:00-16:00
|-
||Pille
|27.02.2017
|10:00-18:00
|-
||Pille
|23.02.2017
|09:00-14:00
|-
||Pille
|22.02.2017
|16:00-19:00
|-
||Pille
|21.02.2017
|15:30-17:00
|-
||Pille
|16.02.2017
|14:30-17:00
|-
||Pille
|15.02.2017
|09:00-18:00
|-
||Alo
|14.02.2017 - 15.02.2017
|18:00-09:00
|-
||Pille
|8.02.2017
|09:00-15:00
|-
||Pille
|7.02.2017
|15:00-18:00
|-
||Madis
|06.02.2017 - 07.02.2017
|21:00-11:00
|-
||Pille
|1.02.2017
|12:00-17:30
|-
||Madis
|31.01.2017 - 01.02.2017
|20:00-10:00
|-
||Pille
|31.01.2017
|10:00-17:30
|-
||Pille
|30.01.2017
|13:00-15:30
|-
||Fred
|25.01.2017
|00:00-11:00
|-
||Pille
|24.01.2017
|10:00-17:00
|-
||Pille
|23.01.2017
|13:00-17:00
|-
||Fred
|23.01.2017
|12:00-13:00
|-
||Pille
|19.01.2017
|10:00-12:00
|-
||Pille
|18.01.2017
|13:00-17:00
|-
||Pille
|13.12
|10:00-15:00
|-
||Pille
|12.12
|10:00-15:00
|-
||Pille
|09.12
|13:00-17:00
|-
||Pille
|07.12
|13:00-17:00
|-
||Pille
|06.12
|13:00-15:00
|-
||Madis
|05.12-06.12
|14:00-10:00
|-
||Pille
|30.11
|13:00-17:00
|-
||Pille
|29.11
|16:00-17:00
|-
||Zane
|29.11 - 30.11.2016
|17:00-10:00
|-
||Kadi-Anne
|14.11 - 15.11.2016
|12:00-12:00
|-
||Kadi-Anne
|10.11 - 11.11.2016
|11:00-12:00
|-
||Kadi-Anne
|03.11 - 04.11.2016
|12:00-12:00
|-
||Kadi-Anne
|02.11 - 03.11.2016
|14:00-12:00
|-
||Kadi-Anne
|19.10 - 20.10.2016
|10:00-13:00
|-
||Kadi-Anne
|05.10 - 06.10.2016
|13:00-12:00
|-
|Kadi-Anne
|26.09 - 27.09.2016
|15:00-12:00
|-
|Georg
|22.09 - 23.09.2016
|15:00-10:00
|-
|Georg
|20.09 - 21.09.2016
|15:00-10:00
|-
|Anna-Liisa
|06.09.2016
|10:00-12:00
|-
|Kaur
|1.09.2016
|8:00-17:00
|-
|Kaur
|31.08.2016
|10:00-18:00
|-
|Anna-Liisa
|30.08.2016
|10:00-18:00
|-
|Anna-Liisa
|29.08.2016
|10:00-18:00
|-
|Anna-Liisa
|12.08.2016
|10:00-17:00
|-
|Anna-Liisa
|10.08.2016
|16:00-17:00
|-
|Anna-Liisa
|30.06.2016
|11:30-14:00
|-
|Carla
|16.05.2016
|10.00-16.00
|-
|Andreas
|11.05.2016
|15:00-17:00
|-
|Hans
|10.05-10.05.2016
|11.00-16.00
|-
|Georg
|10.05-11.05.2016
|16.00-10.00
|-
|Georg
|09.05-10.05.2016
|16.00-10.00
|-
|Arko
|09.05.2016
|10.00-14.00
|-
|Friedrich
|06.05.2016
|10.00-14.00
|-
|Tarmo
|03.05.2016
|14.00-17.00
|-
|Carla
|29.04.2016
|10.00-16.00
|-
|Arko
|25.04.2016
|14.00-17.00
|-
|Alo
|18.04-19.04.2016
|17.00-10.00
|-
|Alo
|15.04-16.04.2016
|16.00-10.00
|-
|Alo
|14.04.2016
|14.00-19.00
|-
|Carla
|14.04.2016
|10.00-14.00
|-
|Alo
|13.04.2016
|12.00-17.00
|-
|Alo
|07.04.2016
|13.00-18.00
|-
|Alo
|06.04.2016
|10.00-19.00
|-
|Alo
|05.04.2016
|10.00-19.00
|-
|Arko & Anna
|04.04 - 05.04.2016
|16.00-10.00
|-
|Alo
|04.04.2016
|11.00-12.00
|-
|Alo
|01.04.2016
|11.00-17.00
|-
|Alo
|24.03.2016
|14.00-19.00
|-
|Alo
|22.03.2016
|14.00-20.00
|-
|Alo
|10.03.2016
|14.00-20.00
|-
|Alo
|09.03.2016
|15.00-20.00
|-
|Alo
|08.03.2016
|14.00-15.30
|-
|Paul
|04.03.2016 - 05.03
|16.00-16.00
|-
|Alo
|03.03.2016-04.03.2016
|13.00-10.00
|-
|Anna-Liisa
|03.03.2016
|9:30-12:00
|-
|Anna-Liisa
|02.03.2016
|15.00-17.00
|-
|Alo
|01.03.2016-02.03.2016
|16.00-10.00
|-
|Anna-Liisa
|26.02.2016
|15.00-17.00
|-
|Georg
|23.02.2016-24.02.2016
|16.00-10.00
|-
|Arko
|22.02.2016
|12.00-17.00
|-
|Anna-Liisa
|18.02.2016
|9.00-16.00
|-
|Anna-Liisa
|15.02.2016
|13.00-16.00
|-
|Georg
|03.02.2016-04.02.2016
|16.00-10.00
|-
|Zane
|19.01.2016 - 20.01.2016
|16.00-10.00
|-
|Paul
|18.01.2015 - 19.01
|16.00-10.00
|-
|Alo/Zane
|15.01.2015 - 16.01.2016
|16.00-10.00
|-
|Anna-Liisa
|11.01.2015
|14.40-17.00
|-
|Anna-Liisa
|08.01.2015
|14.00-17.00
|-
|Alo/Zane
|07.01.2015
|13.00-17.00
|-
|Alo/Zane
|05.01.2015
|10.00-18.00
|-
|Arko
|04.01 - 05.01.2016
|16.00-10.00
|-
|Anna-Liisa
|28.12.2015
|12.00-14.00
|-
|Alo/Zane
|14.12.2015
|14.00-19.00
|-
|Alo
|07.12.2015-08.12.2015
|17.00 - 10.00
|-
|Madis
|06.12.2015-07.12.2015
|19.00 - 9.00
|-
|Alo/Zane
|02.12.2015
|13.00-17.00
|-
|Alo
|01.12.2015
|14.00-17.00
|-
|Alo
|30.11.2015
|14.00-16.00
|-
|Alo
|26.11.2015
|13.00-16.00
|-
|Anna-Liisa
|26.11.2015
|11.00-13.00
|-
|Alo
|25.11.2015
|13.00-16.00
|-
|Alo
|24.11.2015-25.11.2015
|16.00-10.00
|-
|Georg
|23.11.2015-24.11.2015
|16.00-10.00
|-
|Alo/Arko
|20.11.2015-21.11.2015
|16.00 - 10.00
|-
|Alo/Arko
|19.11.2015-20.11.2015
|16.00 - 10.00
|-
|Paul
|18.11.2015-19.11.2015
|16.00 - 10.00
|-
|Anna-Liisa
|18.11.2015
|11.00-16.00
|-
|Pejman/Arko
|17.11.2015-18.11.2015
|16.00-10.00
|-
|Alo
|16.11.2015-17.11.2015
|15.00-10.00
|-
|Anna-Liisa
|13.11.2015
|14.00-18.00
|-
|Fred
|11.11.2015
|10.00-17.00
|-
|Arko
|10.-11.11.2015
|16.00-10.00
|-
|Pejman/Arko
|06.10.2015-
|10.00-18.00
|-
|Fred
|04.11.2015
|10.30-17.00
|-
|Anna-Liisa
|21.10.2015
|9.00-16.00
|-
|Anna-Liisa
|20.10.2015
|10.30-14.00
|-
|Georg/Paul
|14.10.2015-15.10.2015
|17.00-10.00
|-
|-
|Alo
|14.10.2015
|10.00-17.00
|-
|-
|Paul/Georg
|13.10.2015-14.10.2015
|12.00-12.00
|-
|Fred
|30.09.2015
|10:00-18:00
|-
|Kaur
|24.09.2015
|11:00-17:00
|-
|Hans
|15.09.2015 - 16.09.2015
|10:00-15:00
|-
|Hans
|08.09.2015 - 10.09.2015
|15:00-21:00
|-
|Hans
|01.09.2015 - 02.09.2015
|15:00-21:00
|-
|Friedrich
|17.08.2015-18.08.2015
|10.00-17.00
|-
|Paul
|02.07.2015-03.07.2015
|15.00-19.00
|-
|Zane
|29.06 - 30.06
|17:30-10:00
|-
|Zane
|05.06 - 06.06
|17:30-11:30
|-
|Hans
|04.06 - 06.06
|12:45-10:00
|-
|Zane
|03.06 - 04.06
|21:00-10:00
|-
|Inga
|02.06
|15:00-18:00
|-
|Arko
|26.05-27.05
|17:00-10:00
|-
|Zane
|18.05-19.05
|16:00-10:00
|-
|Zane
|14.05-15.05
|16:00-10:00
|-
|Rudolf
|12.05
|14:00-17:00
|-
|Zane
|11.05
|14:00-15:00
|-
|Arko
|11.05 - 12.05.2015
|16:00 - 10:00
|-
|Arko
|07.05 - 08.05.2015
|17:00 - 10:00
|-
|Anna-Liisa
|07.05.2015
|9.30 - 13.00
|-
|Kätlin
|06.05.2015
|11.00 - 00.00
|-
|Anna-Liisa
|30.04.2015
|10.00 - 13.00
|-
|Arko
|24.04.2015 - 24.04.2015
|11.00 - 19.00
|-
|Kätlin
|22.04.2015 - 23.04.2015
|13.00 - 10.00
|-
|Anna-Liisa
|16.04.2015
|10:00 - 11:00
|-
|Inga
|26.03.2015
|12:30 - 17:00
|-
|Inna & Friedrich
|26.03.2015
|10:00 - 12:00
|-
|Arko
|25.03.2015-27.03.2015
|12:00 - 19:00
|-
|Paul
|09.03.2015-10.03.2015
|15.00-12.00 (10.03.2015)
|-
|Anna-Liisa
|09.03.2015
|09:00-12:00
|-
|Inga
|02.03.2015
|12:00-17:00
|-
|Arko
|23.02.2015 - 27.02.2015
|va Anna-Liisa aeg
|-
|Anna-Liisa
|25.02.2015
|9:00-12:00
|-
|Friedrich
|16.02.2015 - 20.02.2015
| 00-24
|-
|Rauno
|07.01.2015 18:00 - 08.01.2015 19:00
|-
|----
|-
|Kätlin
|25.09.2014
|16:00-24.00
|-
|Madis
|06.10.2014
|12:00-14:00
|-
|Rudolf
|06.10.2014
|14:00-17:00
|-
|Kätlin
|16.10.2014
|15:00-24.00
|-
|Paul
|17.11.2014
|13:00-24:00
|-
|Madis
|18.11.2014
|13:00-24:00
|-
|Madis
|19.11.2014
|09:00-22:00
|-
|Kätlin
|20.11.2014
|11:00-24:00
|-
|Anna-Liisa
|21.11.2014
|13:00-15:00
|-
|Kätlin
|03.12.2014
|10:00-24:00
|-
|Kätlin
|04.12.2014
|10:00-24:00
|-
|Kätlin
|05.12.2014
|00:00-24:00
|-
|-
|Arko
|17.12.2014
|12:00-24:00
|-
|Madis
|18.12.2014
|12:00-24:00

Student projects

2018-08-23T07:03:17Z

Gajanee: /* Bioühilduvad elektroaktiivsed polümeerid */

[[Image:IMS poster.png|300px|right]]

''Siin on mõned tegemised, mide meie uurimisgrupi juures on võimalik teha. Tegemist pole lõpliku nimekirjaga ning head tegijad on alati oodatud huvitavate ideedega. Kõikidest teemadest on võimalik edasi minna kuni PhD kaitsmiseni.''
''Huvi korral [[User:Alvo#Contacts|võta ühendust]]''. Mõnede teemade kirjeldused on inglise keeles. Nende teemade juhendajateks on külalisteadlased ja -õppejõud.


= ''' Koostööprojektid ettevõtetega (BSC/MSC theses in collaboration with companies)'''=
== ABB Eesti / ABB Estonia ==
Lõputööde teemad mis on seotud koostööga ABB AS Eestiga. Töö läbi viimisel on kaasatud kaasjuhendaja ABB poolelt koos praktiseerimisvõimalusega ABB-s.

Following topics are conducted in collaboration with ABB Estonian branch. All the topics include co-supervision from ABB.

* [[Utilization of Virtual Reality in Product Development of a VSD cabinet]]
* [[Electric and magnetic field analyses in ALT tester]]
* [[Creation of accurate contact modelling technique for linear FEM-analysis]]

= '''Eksperimentaalne materjaliteadus''' =

==Bioühilduvad elektroaktiivsed polümeerid==

(23.08.2018)

Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditsioonilised aktuaatorid ei ole pehmetes ja painduvates seadmetes rakendatavad, seega on juba aastakümneid uuritud elektroaktiivseid polümeerseid täitureid (''electroactive polymer'' - EAP). EAP-de silmapaistvaks omaduseks on nende multifunktsionaalsus: materjali saab rakendada nii aktuaatori (omadused muutuvad elektrivälja toimel) kui ka sensorina (muutus keskkonna tingimustes põhjustab detekteeritavat elektrivoolu). Elektroaktiivsete polümeeride ühe rakendusena on välja pakutud mitmesugused meditsiiniseadmed (implanteeritavad sensorid, drug delivery seadmed, ...). Nõudmised materjalile on kõrged: ideaalne aktuaator omab laia liigutusulatust juba madalal pingel, on kiire, kerge, vastupidav ning lihtsalt ja odavalt toodetav. Lisaks peab materjal olema bioühilduv.

Antud projekti eesmärk on välja töötada bioühilduv ioonne elektromehaaniline polümeerne täitur (''ionic electroactive polymer'' - IEAP). Uuritav materjal koosneb juhtivpolümeersete või süsinikelektroodide vahele paigutatud biopolümeersest membraanist, elektrolüüdina kasutatakse madala toksilisusega looduslikku päritolu ioonseid vedelikke. Bakalaureuse ja magistritöö teemasid on välja pakkuda projekti erinevates etappides:
* Ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetodeid kasutades
* Süsinikelektroodidega IEAP valmistamine pihustusmeetodil kasutades lähteainetena mitmesuguseid biopolümeere ja madala toksilisusega ioonseid vedelikke
* Erinevate ioonsete vedelike testimine juhtivpolümeersete (polüpürrool) elektroodidega IEAPs: optimaalse polüpürrooli struktuuri ja sünteesiparameetrite otsimine erinevate ioonsete vedelike jaoks
* Biopolümeersete membraanide valmistamine elektrospinnimise teel ja saadud materjalide testimine juhtivpolümeersete IEAP-de valmistamiseks
* ''deep eutectic solvents'' kui alternatiiv ioonsetele vedelikele: kas on rakendatav IEAP-des?

== Süsinikelektroodidega polümeersed täiturid==

Kunstlihaseid ehk elektroaktiivseid polümeerseid täitureid on väga palju erinevaid. Nanopoorsest süsinikust elektroodidega ioonsed täiturid töötavad madalpingel ning neil on mitmed eelised kasutamiseks mikroseadmetes ja meditsiinis. Hetkel on uurimisel kaks suunda. Esimese eesmärk on arendada kunstlihasetes kasutatavaid ioonvedelik-süsinik-polümeer komposiite, kasutades selleks erinevaid süsinikmaterjale (süsinikaerogeeli, karbiidset süsinikku, süsiniknanotorusid jpt), ioonseid vedelikke, polümeere. Teine suund keskendub uute kunstlihase valmistamise tehnoloogiate rakendamisele. Uurime materjalide omadusi ja toimimismehhanisme, et kasutada neid aktuaatorite ning sensoritena. Bakalaureuse- ja magistritööks on teemasid mõlemast suunast:
* uut tüüpi nanomaterjali kasutamine täituri elektroodina
* süsinik-kserogeeli valmistamine ja struktuur-omadus seoste uurimine
* täituri valmistamine vurrkatmise meetodil (spin-coating)

==Kunstlihased kosmoserakendustes==

Meie poolt valmistatavad materjalid on kerged ning juhitavad madalate elektripingetega. Seetõttu pakuvad nad huvi kosmosetehnoloogia seadmete valmistajatele.
Töö eesmärgiks on uurida kiirguse, temperatuuri jpt kosmoses materjalidele mõjuvate kahjustavate toimete mõju.

==Juhtivpolümeeridel põhinevate mitmekihiliste kunstlihaste valmistamine ja iseloomustamine==

Kunstlihased, sensorid ja energiahõiveseadmed on elektritjuhtivate orgaaniliste polümeeride uudsemateks ja põnevamateks arengusuundadeks. Neid loodetakse kasutada meditsiinis, robootikas, kosmose- ja militaartööstuses. Enne laiaulatuslikku kasutuselevõttu on siiski vaja veel teha hulk arendustööd. Mitmekihilise disain loob eeldused juhtivpolümeerse materjali paremaks kontrollimiseks ning tema omaduste parandamiseks. TÜ IMS laboris on välja töötatud uudsed sünteesimeetodid metallivabade kunstlihaste valmistamiseks. Senistel lihtsa ühekihilise struktuuriga materjalidel on mitmeid puudusi (juhtuvuse langus, tundlikus väliskeskkonna mõjudele). Aktuatsiooni tekitavale polümeerikihile vastupidise ioonliikuvusega kihtide lisamine loob eelduse neid puudusi vältida.

==Mikroakude valmistamine printimistehnoloogiat kasutades==

(20.09.2017)

Mikroakude arendamise vajalikkusest on juttu allpool lõigus [[#See also|Liitium-ioon akude arhitektuuri optimeerimine arvutisimulatsioonide abil]]. Printimine on potentsiaalne tehnoloogia 3D mikroakude valmistamiseks, ka tööstuslikus mastaabis, sest võimaldab kontrollitavalt luua funktsionaalsetest materjalidest erinevaid keerukaid kihilisi struktuure. Seonduvad uurimistöö teemad on:
* sobivate omadustega süsinikpulbri sünteesimise uurimine
*elektroodide ja membraani printimissegu koostise väljatöötamine
*3D struktuuride printimine ja iseloomustamine

==Süsinikelektroodidega täiturmaterjali tööstusliku tootmise ettevalmistamine==

Projekti sisuks on välja töötada materjal ja metoodika kuidas valmistada süsinikelektroodidega täitureid tööstuslikke protsesse kasutades. Töö laiem eesmärk on selliste materjalide masstootmine.

==Biokütuseelement==

Biokütuseelement on bioreaktor, mis muundab orgaaniliste ühendite keemiliste sidemete energia elektrienergiaks. Näiteks glükoosil ja hapnikul töötavad biokütuseelemendid, mis on võimelised energiat korjama erinevates bioloogilistest vedelikest, on paljulubavad seadmed rakendamiseks energiaallikatena mitmesugustes bioelektrilistes implantaatides nagu insuliinipumbad, ravimidosaatorid, närvistimulaatorid, südamestimulaatorid. Antud projekt tegeleb uudse elektroodimaterjali väljatöötamisega biokütuseelemendi jaoks.

==Pehmed kantavad sensorid==

Kõikvõimaliku kantava elektroonika populaarsuse kasv on suurendanud huvi pehmete sensorite vastu, mis mõõdaksid objektide (näiteks inimese keha) kuju ja asendit ilma liikumist takistamata. Senise uurimistöö käigus on välja töötatud sensortald, mis võimaldab sportlasel jälgida jala aluse rõhu jaotust aga ka igal sammul rakendatavat võimsust. Mitmekihiliste elastsete sensorite võrgustik suudab jälgida kehakuju muutust või liikumist, mõõtes korraga nii pikenemist kui painet. Uurimistöö jätkub erinevate uudsete jala- ja keha sensorite väljatöötamiseks.

==Multifunktsionaalsete tekstiilmaterjalide arendus==
[[File:AAC CaSO4.jpg|thumb|CaSO4 crystal in autoclaved aerated concrete, SEM 500x]]
Tänapäeval oodatakse kangastelt enam kui lihtsalt keha soojas hoidmist, eriti spordi- või militaarrakendustes. Projekti eesmärgiks on välja töötada uudne kangas, mis oleks võrreldav tugevate erikangastega, olles neist pehmem ja kergem, ei määrduks ega võtaks vett sisse ning oleks samas hingav. Selleks tuleb leida nii optimaalsed kiumaterjalid kui nendele sobiv nanotehnoloogiline järeltöötlus.

==Materjalide arendus tööstusele==

Projekti raames lahendatakse erinevate tööstuspartnerite tehnoloogilisi probleeme või arendatakse neile uusi tooteid. Mõned näited:
* mittepõlev silikoonvaht istmepolstrite jm pehmenduste jaoks;
* mikroarmatuuriga poorbetoon, mis oleks korraga konstruktsiooni- ja isolatsioonimaterjal;
* kiirbetooni omaduste optimeerimine
* šlakigraanulite taaskasutus
* klaasi keemiline karastamine

= '''Arvutieksperimendid ja materjalide simuleerimine''' =

==Materjalidefektide simuleerimine kõrgsageduslikes elektriväljades==
[[Image:Reklaamposter.png|right|thumb|200px]]
Nutikas tudeng, kes sa tunned huvi tänapäeva tippteaduse vastu ning soovid oma lõputööd teha CERN-iga seotud teemal ning tegutsedes CERN-is! Võta ühendust ning osale uue CERN-is baseeruva kiirendi väljatöötamisel!

Kompaktne lineaarpõrguti (CLIC, http://clic-study.web.cern.ch/) on CERN-is arendatav uue põlvkonna lineaarkiirendi, kus osakeste kiirendamine toimub sirgjoonelistel trajektooridel. Lineaarkiirendi rakendusvaldkondadeks on näiteks standardmudeli järgne füüsika (physics beyond the standard model), Higgsi bosoni täppismõõtmised ning meditsiinilised valdkonnad, nagu näiteks vähiravi. Planeeritav seade on 50 km pikk ning sellega jõutakse energiateni 0.5 TeV - 5 TeV. Saavutamaks sellist energiat, kasutatakse kiirendavat elektrivälja, mis ulatub 100-150 MV/m. Sellistes kõrgetes elektriväljades avaldub olulise probleemina aga sage elektriliste läbilöökide tekkimine kiirendi elektroodidel.

Läbilöögid avalduvad vaakumkaartena (kaarlahendus vaakumis), ning üldiselt eeldatakse, et vaakumkaar algab elektrivälja võimendavate nanoskaalas olevatelt nõelasarnastelt pinnadefektidelt, nende pinnadefektide tekkemehhanism on ebaselge. '''Elektriliste läbilöökide kahandamine alla kriitilise piiri on keskse tähtsusega probleemiks CLIC-i ehitamisel!'''

Üks lubavamaid meetodeid kiirendi struktuuri parandamiseks on uute materjalide leidmine, mis suudavad taluda kõrgeid elektrivälju ning kiireid elektriväljade muutusi. Võtmeprobleemiks uute materjalide leidmisel on arusaamine füüsikalistest protsessidest, mis toimuvad materjalis läbilöögi eel ning ajal. Uurimustöös kasutatakse erinevaid arvutusmeetodeid, nagu '''molekulaardünaamika, lõplike elementide meetod ja kineetiline Monte-Carlo''', selgitamaks elektriliste läbilöökideni viivate pinnadefektide tekkepõhjuseid. Töös vajalike aruvutisimulatsioonide läbiviimine tähendab, et suures plaanis kasutatakse nn. '''„multiscale“ simulatsioone''', millega kaetakse materjalide simuleerimine alates atomistlikust skaalast kuni makroskaalani.

'''Mõningad näited lõputööde teemadest on:'''

1. Vase polükristallide mõju materjali sisepingetele lõplike elementide meetodiga

2. Raadiosageduslike elektriväljade mõju pinnadefektidele

3. Pinnadefektide mõju elektroodi keskmisele väljumistööle

4. Elektrivälja mõju pinnadefektide genereerimisele - in situ SEM ja arvutisimulatsioonide abil

PS! Võimalik osalemine CERNi suvetudengite programmides ning suvine CERNis praktiseerimine.

==Kunstlihaste materjalide uurimine erinevate arvutisimulatsioonimeetodite abil==

* Tegemist on materjaliga, mida välise elektriväljaga on võimalik panna kuju muutma: painduma, punduma, kokku tõmbuma - nagu teeb reaalne lihas
* kunstlihase materjal võib ka reageerida välisele mehaanilisele kujumuutusele elektrilise signaaliga
* kunstlihas tegutseb hääletult, olles ise mõõtmetelt väga väike
* kunstlihase materjalidena uuritakse selliseid "hitte" nagu grafeen ja ioonvedelik
* arvutisimulatsioonid viivad sind materjali "sisse", võimaldades näha seda, mis katses jääb varju, anda infot toimuvate protsesside kohta ja näpunäiteid materjalide parendamiseks
* tahad teda, kuidas liigutab 2 cm pikkune riba kunstlihast? võta lõplike lementide meetod ja sa näed ära pinged ja deformatsioonid kujumuutmisel
* tahad teada, kuidas elektroodide kuju muutmine mõjutab liitiumioonaku mahtuvust - seda, kui kaua sinu elektriauto mööda Tartu-Tallinna maanteed suudaks kihutada? võta lõplike elementide meetod ja sa saad välja arvutada aku tühjenemise kiiruse sinu elektriauto toitmisel
* tahad teada, kuidas liiguvad ja mõjutavad üksteist aatomid ja molekulid kunstlihases ja liitiumioonaku elektroodides ning elektrolüüdis? võta molekulaardünaamiline simulatsioon ja sa saad siseneda maailma, mis on 10000 korda väiksem sinu juuksekarva läbimõõdust
* tahad virtuaalselt istuda iga aatomi peal ja näha, kuidas ühe aatomi elektronpilv lööb teise oma segamini? võta kvantkeemiline molekulaardünaamika ja sinu sõit lainefunktsioonide harjadel on pöörasem kui Ristna neemel Katja ajal.

==Liitium-ioon akude arhitektuuri optimeerimine arvutisimulatsioonide abil==

Kaasaskantav mikroakutoide on oluliseks faktoriks paljudes arenevates tehnoloogiasuundades, kuna mikroelektroonika mõõtmete vähenemine on jätnud kaugele seljataha väikesemõõduliste vooluallikate arengu. Sobivate kaasaskantavate vooluallikate vähene energiamahtuvus on saamas takistuseks mitmete tehnoloogiasuundade nagu kaasaskantavate arvutusseadmete (Weareable Computing Technology e. WCT), mikroelektromehaaniliste seadmete (MEMS), biomeditsiiniliste mikromasinate arengus. Üheks võtmeprobleemiks selliste seadmete edukaks toimimiseks on nende varustamine vooluallikatega, mis ühelt küljelt tagavad seadme piisava energiahulgaga varustamise ning teiselt küljelt, on võimalikult väikesemõõduised ning kergekaalulised. Sellise konfiguratsiooni juures tulevad ilmsiks olemasolevate, olemuselt kahemõõtmeliste (2D) liitium-ioonakude puudused – nii väikeste ruum- ja pindalade puhul ei ole võimalik saavutada piisavaid energiatihedusi. Seda probleemi võimaldab lahendada 3D mikroakude (MB) kasutusele võtmine.
Liitiumioonakude arhitektuuri optimeerimise eesmärgiks on valmistada töötav 3D-MB, mille energiatihedus ning mahtuvus on vähemalt suurusjärgu võrra suuremad praegu kasutusel olevate akude omadest. Toimiva 3D-MB välja töötamiseks arendatakse ja uuritakse erinevaid mikroaku arhitektuure, neist sobiva väljavalimist ning optimeerimist lihtsustavad oluliselt teoreetilised, arvutisimulatsioonidega läbi viidavad uuringud, mis võimaldavad testida erinevaid 3D-MB arhitektuure, lahendada optimeerimisülesandeid elektroodide optimaalse geomeetria leidmiseks; optimeerida elektroodi pinda; uurida terve aku käitumist laadimisel-tühjakslaadimisel; optimeerida sobivaid mikroaku arhitektuure.
Meetodid makrotasandis, mida selliste uuringute läbiviimiseks kasutatakse on lõplike elementide meetod (LEM) ning mikrotasandil molekulaardünaamilise simulatsiooni meetod (MD). Simulatsioonide läbiviimiseks kasutatakse LEM-i puhul tarkvarapakette COMSOL Multiphysics ja Elmer ning MD puhul tarkvarapaketti dl_poly.

= '''Aktuaatorid, seadmed ja nende juhtimine''' =
==IPMC elektromehhaanilisi omadusi uuriva seadme juhtimine==

Töö eesmärgiks on koostada eksperimentaalne seade, mis mõõdab elektroaktiivsete polümeeride elektromehaanilisi omadusi. Materjale kasutatakse kunstlihastena erinevates rakendustes. Töö tulemuseks peab valmima moodul, mis võimaldab seadet juhtuda USB kaudu.

==IPMC täitureid kasutava autonoomse seadme konstrueerimine==

Eesmärgiks on nn kunstlihaeid kasutavate materjalide abil liikuvate autonoomsete seadmete konstrueerimine ning töö kirjeldamine. Valik ideid: "putukas", ratas, minipurilennuk, mikrohumanoid jne.

==Süsinik-polümeermaterjalidest täiturite juhtimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi. St. vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomine, nende mudelite kirjeldamine ning eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureus, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

==IPMC/süsinik polümeermaterjalidest energiakogujate uurimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi eesmärgiga vinkeskkonnas olevate vibratsioonidest saadav energia muundada elektrienergiaks. Töö kujutab endast vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomist, nende mudelite kirjeldamine nin eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureuse, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

== Lahedad ideed kunstlihaste rakendamiseks==
=== Ilmekas uksekoputi ===

Teha kunstlihastest ilmekas uksekoputi, vt. http://www.youtube.com/watch?feature=player_detailpage&v=-Kee7iyp_3U&list=TLC5Famb33RxE

= '''Signal and Image Processing''' ''(Signaali ja Pilditöötlus)'' =

''If you are interested in doing any of the following projects as your BSc project or if you would like to get more information please feel free to contact me via shb-AT-ut-DOT-ee''

For full list of project description please visit http://icv.ims.ut.ee/projectspage.html [[http://icv.ims.ut.ee/projectspage.html]]

= '''Robotics''' =
== Click here for [[student projects in robotics]] ==

= '''Partneritega seotud teemad''' =

==Kõrgkoolide õppekavade masinõppel põhinev analüüs==

Projekti eesmärgiks on arendada masinõppel põhinev tarkvara, mis suudaks automaatselt analüüsida ja kaardistada Tartu Ülikooli õppekavade ning nendes loetavate ainete sisu viisil, et oleks jooksvalt võimalik hinnata õppekvaliteeti ja selle vastavust tööturu reaalsetele vajadustele. '''Eriti sobilik tudengitele,''' kellel on lisaks erialasele huvile soov kokkupuutuda '''startup''' ja tehnoloogia ettevõttlusega.

'''Bakalaureuse- või magistritöö käigus loodav praktiline tarkvaralahendus:'''
* analüüsib õppekavade terviklikkust, erinevate moodulite ja õppeainete vaheliste seoste sidusust, vastavust õppekava ja mooduli üldeesmärkidele,
* analüüsib jooksvalt õppekavade vastavust tööturu vajadustele lähtuvalt töötajatele reaalselt esitatavatest kvalifikatsiooni nõuetest,
* annab õppejõududele ja programmijuhtidele infot võimalikest kattuvustest, puuduvatest eelteadmistest õppeainetele ja arenguvajadustest,
* võimaldab arendada ühismooduleid ja õppeaineid erinevate õppekavade vahel eeldusteadmiste lünkadeta ja kattuvusteta,
* võimaldab hinnata ja võrrelda juba olemasolevate ja veel loodavate õppekavade konkurentsivõimet teiste koolide sarnaste õppekavadega.

'''Antud lõputöö kontekstis olulised märksõnad on:'''
* suurandmed ja andmekaeve (big data & data mining)
* masinõppe algoritmid (machine learning)
* andmete visualiseerimine (data visualization)

Lõputööd juhendab Aleksander Tõnnisson, kes on teinud üle 40-ne investeeringu iduettevõtetesse.

==Mehhanoelektriliste andurite uurimine==

Töö eesmärgiks on eksperimentaalselt uurida erinevate mehaanilist liigutust elektriliseks muundavate materjalide omadusi. Töö hõlmab eksperimendi konstrueerimist ja arvutijuhitavate mõõtmiste teostamist LabVIEW keskkonnas. Sobib hästi arvutitehnika, füüsika ja materjaliteaduse tudengitele.

==Robotmannekeen rõivatööstusele==

Projekti eesmärgiks on arendada välja inimkeha kujuline mannekeeni alakeha rõivatööstusele kiirendamaks ning parendamaks disainerrõivaste väljatöötamist.
Projektis on vaja konstrueerida mehaanika sõlmed, realiseerida elektroonika juhtsõlmed, modeleerida ning luua algoritmid mannekeeni välispinna juhtimiseks ning arendada välja süsteemi kontroll tarkvara. Samuti on vaja arendada välja kasutajatarkvara. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

Projektil on ka konkreetne rakendus vt [http://www.fits.me www.fits.me]

==Puutetundlik sensor robotmannekeenile ==

Projekti eesmärgiks on arendada inimkeha kujuline mannekeenile puutetundlike "naha" välja arendamine.
Projektis on vaja uurida ja testida erinevaid sensoreid, Leida olulised mõõtevahemikud ja mõõtetäpsused vastavalt vajadusele rakenduses. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

= '''Õppetööga seotud''' =
==Sensori-anduri töö uurimine ja juhendmaterjali koostamine==

Töö eesmärgiks on eksperimentaalselt parametriseerida robootikas/automaatikas kasutatav sensor/täitur ning tulemuse põhjal koostada protokoll ja metoodika selle kasutamiseks.

== Juhendmaterjali koostamine koolirobootika tarbeks==

Töö eesmärgiks on koostada õpetajatele juhendmaterjale ja põnevaid tööülesandeid, aga samuti ülesandeid, mis aitavad lastel õppida füüsikat, matemaatikat, keemiat ja bioloogiat.
-->

=Üldine info bakalaureuse- ja magistritöö tegijatele=

Teil on kaks juhendajat. Eeldame, et te vähemalt kord nädalas võtate vähemalt ühe juhendajaga kontakti ja arutate läbi oma mured ja tegemised. Lisaks ootame tudengitelt aktiivset osavõttu kord nädalas toimuvast labori seminarist ja journal club'ist, kus harjutatakse avalikku esinemist, et kaitsmisel oleks lihtsam.

Töö esimene versioon peab olema esitatud hiljemalt 1. maiks. Hilinemiseks sobivad ainult dokumentaalselt tõestatavad meditsiinilised põhjused. Esimene version peab sisaldama:
# sissejuhatust, mis räägib, miks projekti tulemus on vajalik ja mida teised selles valdkonnas maailmas teinud on;
# projekti teoreetilisi/matemaatilisi/mudeli aluseid lahti kirjutatuna;
# tehtud tegevuse detailset kirjeldust (detaile pole kunagi liiga palju, delete on lihtsaim funktsioon, mida juhendaja teie kirjaliku töö ümber kirjutamisel :) teha saab);
# töö tulemusi, st kas mõõtmistulemusi või seadme töötava! prototüübi tehniline kirjeldust ja seadet ennast;
# hinnangut oma tööle, st töö tulemuste edasise arengu analüüsi, tulemuste analüüsi ja hinnangut töö tulemuse kvaliteedile.

'''Töö kaitsmisele lubamiseks on kohustuslik läbida laborisisene eelkaitsmine, vajadusel korduv'''. Eelkaitsmiste ajagraafik kuulutatakse välja igal aastal aprillis. Arvestada tuleb ajaliste piirangutega- Eelkaitsmisele õigeaegne registreerumine on tudengi kohustus.

Student projects

2018-08-23T07:01:59Z

Gajanee: /* Biorakendusteks sobiv "kunstlihas" */

[[Image:IMS poster.png|300px|right]]

''Siin on mõned tegemised, mide meie uurimisgrupi juures on võimalik teha. Tegemist pole lõpliku nimekirjaga ning head tegijad on alati oodatud huvitavate ideedega. Kõikidest teemadest on võimalik edasi minna kuni PhD kaitsmiseni.''
''Huvi korral [[User:Alvo#Contacts|võta ühendust]]''. Mõnede teemade kirjeldused on inglise keeles. Nende teemade juhendajateks on külalisteadlased ja -õppejõud.


= ''' Koostööprojektid ettevõtetega (BSC/MSC theses in collaboration with companies)'''=
== ABB Eesti / ABB Estonia ==
Lõputööde teemad mis on seotud koostööga ABB AS Eestiga. Töö läbi viimisel on kaasatud kaasjuhendaja ABB poolelt koos praktiseerimisvõimalusega ABB-s.

Following topics are conducted in collaboration with ABB Estonian branch. All the topics include co-supervision from ABB.

* [[Utilization of Virtual Reality in Product Development of a VSD cabinet]]
* [[Electric and magnetic field analyses in ALT tester]]
* [[Creation of accurate contact modelling technique for linear FEM-analysis]]

= '''Eksperimentaalne materjaliteadus''' =

==Bioühilduvad elektroaktiivsed polümeerid==

(23.08.2018)

Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditsioonilised aktuaatorid ei ole pehmetes ja painduvates seadmetes rakendatavad, seega on juba aastakümneid uuritud elektroaktiivseid polümeerseid täitureid (''electroactive polymer'' - EAP). EAP-de silmapaistvaks omaduseks on nende multifunktsionaalsus: materjali saad rakendada nii aktuaatori (omadused muutuvad elektrivälja toimel) kui ka sensorina (muutus keskkonna tingimustes põhjustab detekteeritavat elektrivoolu). Elektroaktiivsete polümeeride ühe rakendusena on välja pakutud mitmesugused meditsiiniseadmed (implanteeritavad sensorid, drug delivery seadmed, ...). Nõudmised materjalile on kõrged: ideaalne aktuaator omab laia liigutusulatust juba madalal pingel, on kiire, kerge, vastupidav ning lihtsalt ja odavalt toodetav. Lisaks peab materjal olema bioühilduv.

Antud projekti eesmärk on välja töötada bioühilduv ioonne elektromehaaniline polümeerne täitur (''ionic electroactive polymer'' - IEAP). Uuritav materjal koosneb juhtivpolümeersete või süsinikelektroodide vahele paigutatud biopolümeersest membraanist, elektrolüüdina kasutatakse madala toksilisusega looduslikku päritolu ioonseid vedelikke. Bakalaureuse ja magistritöö teemasid on välja pakkuda projekti erinevates etappides:
* Ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetodeid kasutades
* Süsinikelektroodidega IEAP valmistamine pihustusmeetodil kasutades lähteainetena mitmesuguseid biopolümeere ja madala toksilisusega ioonseid vedelikke
* Erinevate ioonsete vedelike testimine juhtivpolümeersete (polüpürrool) elektroodidega IEAPs: optimaalse polüpürrooli struktuuri ja sünteesiparameetrite otsimine erinevate ioonsete vedelike jaoks
* Biopolümeersete membraanide valmistamine elektrospinnimise teel ja saadud materjalide testimine juhtivpolümeersete IEAP-de valmistamiseks
* ''deep eutectic solvents'' kui alternatiiv ioonsetele vedelikele: kas on rakendatav IEAP-des?

== Süsinikelektroodidega polümeersed täiturid==

Kunstlihaseid ehk elektroaktiivseid polümeerseid täitureid on väga palju erinevaid. Nanopoorsest süsinikust elektroodidega ioonsed täiturid töötavad madalpingel ning neil on mitmed eelised kasutamiseks mikroseadmetes ja meditsiinis. Hetkel on uurimisel kaks suunda. Esimese eesmärk on arendada kunstlihasetes kasutatavaid ioonvedelik-süsinik-polümeer komposiite, kasutades selleks erinevaid süsinikmaterjale (süsinikaerogeeli, karbiidset süsinikku, süsiniknanotorusid jpt), ioonseid vedelikke, polümeere. Teine suund keskendub uute kunstlihase valmistamise tehnoloogiate rakendamisele. Uurime materjalide omadusi ja toimimismehhanisme, et kasutada neid aktuaatorite ning sensoritena. Bakalaureuse- ja magistritööks on teemasid mõlemast suunast:
* uut tüüpi nanomaterjali kasutamine täituri elektroodina
* süsinik-kserogeeli valmistamine ja struktuur-omadus seoste uurimine
* täituri valmistamine vurrkatmise meetodil (spin-coating)

==Kunstlihased kosmoserakendustes==

Meie poolt valmistatavad materjalid on kerged ning juhitavad madalate elektripingetega. Seetõttu pakuvad nad huvi kosmosetehnoloogia seadmete valmistajatele.
Töö eesmärgiks on uurida kiirguse, temperatuuri jpt kosmoses materjalidele mõjuvate kahjustavate toimete mõju.

==Juhtivpolümeeridel põhinevate mitmekihiliste kunstlihaste valmistamine ja iseloomustamine==

Kunstlihased, sensorid ja energiahõiveseadmed on elektritjuhtivate orgaaniliste polümeeride uudsemateks ja põnevamateks arengusuundadeks. Neid loodetakse kasutada meditsiinis, robootikas, kosmose- ja militaartööstuses. Enne laiaulatuslikku kasutuselevõttu on siiski vaja veel teha hulk arendustööd. Mitmekihilise disain loob eeldused juhtivpolümeerse materjali paremaks kontrollimiseks ning tema omaduste parandamiseks. TÜ IMS laboris on välja töötatud uudsed sünteesimeetodid metallivabade kunstlihaste valmistamiseks. Senistel lihtsa ühekihilise struktuuriga materjalidel on mitmeid puudusi (juhtuvuse langus, tundlikus väliskeskkonna mõjudele). Aktuatsiooni tekitavale polümeerikihile vastupidise ioonliikuvusega kihtide lisamine loob eelduse neid puudusi vältida.

==Mikroakude valmistamine printimistehnoloogiat kasutades==

(20.09.2017)

Mikroakude arendamise vajalikkusest on juttu allpool lõigus [[#See also|Liitium-ioon akude arhitektuuri optimeerimine arvutisimulatsioonide abil]]. Printimine on potentsiaalne tehnoloogia 3D mikroakude valmistamiseks, ka tööstuslikus mastaabis, sest võimaldab kontrollitavalt luua funktsionaalsetest materjalidest erinevaid keerukaid kihilisi struktuure. Seonduvad uurimistöö teemad on:
* sobivate omadustega süsinikpulbri sünteesimise uurimine
*elektroodide ja membraani printimissegu koostise väljatöötamine
*3D struktuuride printimine ja iseloomustamine

==Süsinikelektroodidega täiturmaterjali tööstusliku tootmise ettevalmistamine==

Projekti sisuks on välja töötada materjal ja metoodika kuidas valmistada süsinikelektroodidega täitureid tööstuslikke protsesse kasutades. Töö laiem eesmärk on selliste materjalide masstootmine.

==Biokütuseelement==

Biokütuseelement on bioreaktor, mis muundab orgaaniliste ühendite keemiliste sidemete energia elektrienergiaks. Näiteks glükoosil ja hapnikul töötavad biokütuseelemendid, mis on võimelised energiat korjama erinevates bioloogilistest vedelikest, on paljulubavad seadmed rakendamiseks energiaallikatena mitmesugustes bioelektrilistes implantaatides nagu insuliinipumbad, ravimidosaatorid, närvistimulaatorid, südamestimulaatorid. Antud projekt tegeleb uudse elektroodimaterjali väljatöötamisega biokütuseelemendi jaoks.

==Pehmed kantavad sensorid==

Kõikvõimaliku kantava elektroonika populaarsuse kasv on suurendanud huvi pehmete sensorite vastu, mis mõõdaksid objektide (näiteks inimese keha) kuju ja asendit ilma liikumist takistamata. Senise uurimistöö käigus on välja töötatud sensortald, mis võimaldab sportlasel jälgida jala aluse rõhu jaotust aga ka igal sammul rakendatavat võimsust. Mitmekihiliste elastsete sensorite võrgustik suudab jälgida kehakuju muutust või liikumist, mõõtes korraga nii pikenemist kui painet. Uurimistöö jätkub erinevate uudsete jala- ja keha sensorite väljatöötamiseks.

==Multifunktsionaalsete tekstiilmaterjalide arendus==
[[File:AAC CaSO4.jpg|thumb|CaSO4 crystal in autoclaved aerated concrete, SEM 500x]]
Tänapäeval oodatakse kangastelt enam kui lihtsalt keha soojas hoidmist, eriti spordi- või militaarrakendustes. Projekti eesmärgiks on välja töötada uudne kangas, mis oleks võrreldav tugevate erikangastega, olles neist pehmem ja kergem, ei määrduks ega võtaks vett sisse ning oleks samas hingav. Selleks tuleb leida nii optimaalsed kiumaterjalid kui nendele sobiv nanotehnoloogiline järeltöötlus.

==Materjalide arendus tööstusele==

Projekti raames lahendatakse erinevate tööstuspartnerite tehnoloogilisi probleeme või arendatakse neile uusi tooteid. Mõned näited:
* mittepõlev silikoonvaht istmepolstrite jm pehmenduste jaoks;
* mikroarmatuuriga poorbetoon, mis oleks korraga konstruktsiooni- ja isolatsioonimaterjal;
* kiirbetooni omaduste optimeerimine
* šlakigraanulite taaskasutus
* klaasi keemiline karastamine

= '''Arvutieksperimendid ja materjalide simuleerimine''' =

==Materjalidefektide simuleerimine kõrgsageduslikes elektriväljades==
[[Image:Reklaamposter.png|right|thumb|200px]]
Nutikas tudeng, kes sa tunned huvi tänapäeva tippteaduse vastu ning soovid oma lõputööd teha CERN-iga seotud teemal ning tegutsedes CERN-is! Võta ühendust ning osale uue CERN-is baseeruva kiirendi väljatöötamisel!

Kompaktne lineaarpõrguti (CLIC, http://clic-study.web.cern.ch/) on CERN-is arendatav uue põlvkonna lineaarkiirendi, kus osakeste kiirendamine toimub sirgjoonelistel trajektooridel. Lineaarkiirendi rakendusvaldkondadeks on näiteks standardmudeli järgne füüsika (physics beyond the standard model), Higgsi bosoni täppismõõtmised ning meditsiinilised valdkonnad, nagu näiteks vähiravi. Planeeritav seade on 50 km pikk ning sellega jõutakse energiateni 0.5 TeV - 5 TeV. Saavutamaks sellist energiat, kasutatakse kiirendavat elektrivälja, mis ulatub 100-150 MV/m. Sellistes kõrgetes elektriväljades avaldub olulise probleemina aga sage elektriliste läbilöökide tekkimine kiirendi elektroodidel.

Läbilöögid avalduvad vaakumkaartena (kaarlahendus vaakumis), ning üldiselt eeldatakse, et vaakumkaar algab elektrivälja võimendavate nanoskaalas olevatelt nõelasarnastelt pinnadefektidelt, nende pinnadefektide tekkemehhanism on ebaselge. '''Elektriliste läbilöökide kahandamine alla kriitilise piiri on keskse tähtsusega probleemiks CLIC-i ehitamisel!'''

Üks lubavamaid meetodeid kiirendi struktuuri parandamiseks on uute materjalide leidmine, mis suudavad taluda kõrgeid elektrivälju ning kiireid elektriväljade muutusi. Võtmeprobleemiks uute materjalide leidmisel on arusaamine füüsikalistest protsessidest, mis toimuvad materjalis läbilöögi eel ning ajal. Uurimustöös kasutatakse erinevaid arvutusmeetodeid, nagu '''molekulaardünaamika, lõplike elementide meetod ja kineetiline Monte-Carlo''', selgitamaks elektriliste läbilöökideni viivate pinnadefektide tekkepõhjuseid. Töös vajalike aruvutisimulatsioonide läbiviimine tähendab, et suures plaanis kasutatakse nn. '''„multiscale“ simulatsioone''', millega kaetakse materjalide simuleerimine alates atomistlikust skaalast kuni makroskaalani.

'''Mõningad näited lõputööde teemadest on:'''

1. Vase polükristallide mõju materjali sisepingetele lõplike elementide meetodiga

2. Raadiosageduslike elektriväljade mõju pinnadefektidele

3. Pinnadefektide mõju elektroodi keskmisele väljumistööle

4. Elektrivälja mõju pinnadefektide genereerimisele - in situ SEM ja arvutisimulatsioonide abil

PS! Võimalik osalemine CERNi suvetudengite programmides ning suvine CERNis praktiseerimine.

==Kunstlihaste materjalide uurimine erinevate arvutisimulatsioonimeetodite abil==

* Tegemist on materjaliga, mida välise elektriväljaga on võimalik panna kuju muutma: painduma, punduma, kokku tõmbuma - nagu teeb reaalne lihas
* kunstlihase materjal võib ka reageerida välisele mehaanilisele kujumuutusele elektrilise signaaliga
* kunstlihas tegutseb hääletult, olles ise mõõtmetelt väga väike
* kunstlihase materjalidena uuritakse selliseid "hitte" nagu grafeen ja ioonvedelik
* arvutisimulatsioonid viivad sind materjali "sisse", võimaldades näha seda, mis katses jääb varju, anda infot toimuvate protsesside kohta ja näpunäiteid materjalide parendamiseks
* tahad teda, kuidas liigutab 2 cm pikkune riba kunstlihast? võta lõplike lementide meetod ja sa näed ära pinged ja deformatsioonid kujumuutmisel
* tahad teada, kuidas elektroodide kuju muutmine mõjutab liitiumioonaku mahtuvust - seda, kui kaua sinu elektriauto mööda Tartu-Tallinna maanteed suudaks kihutada? võta lõplike elementide meetod ja sa saad välja arvutada aku tühjenemise kiiruse sinu elektriauto toitmisel
* tahad teada, kuidas liiguvad ja mõjutavad üksteist aatomid ja molekulid kunstlihases ja liitiumioonaku elektroodides ning elektrolüüdis? võta molekulaardünaamiline simulatsioon ja sa saad siseneda maailma, mis on 10000 korda väiksem sinu juuksekarva läbimõõdust
* tahad virtuaalselt istuda iga aatomi peal ja näha, kuidas ühe aatomi elektronpilv lööb teise oma segamini? võta kvantkeemiline molekulaardünaamika ja sinu sõit lainefunktsioonide harjadel on pöörasem kui Ristna neemel Katja ajal.

==Liitium-ioon akude arhitektuuri optimeerimine arvutisimulatsioonide abil==

Kaasaskantav mikroakutoide on oluliseks faktoriks paljudes arenevates tehnoloogiasuundades, kuna mikroelektroonika mõõtmete vähenemine on jätnud kaugele seljataha väikesemõõduliste vooluallikate arengu. Sobivate kaasaskantavate vooluallikate vähene energiamahtuvus on saamas takistuseks mitmete tehnoloogiasuundade nagu kaasaskantavate arvutusseadmete (Weareable Computing Technology e. WCT), mikroelektromehaaniliste seadmete (MEMS), biomeditsiiniliste mikromasinate arengus. Üheks võtmeprobleemiks selliste seadmete edukaks toimimiseks on nende varustamine vooluallikatega, mis ühelt küljelt tagavad seadme piisava energiahulgaga varustamise ning teiselt küljelt, on võimalikult väikesemõõduised ning kergekaalulised. Sellise konfiguratsiooni juures tulevad ilmsiks olemasolevate, olemuselt kahemõõtmeliste (2D) liitium-ioonakude puudused – nii väikeste ruum- ja pindalade puhul ei ole võimalik saavutada piisavaid energiatihedusi. Seda probleemi võimaldab lahendada 3D mikroakude (MB) kasutusele võtmine.
Liitiumioonakude arhitektuuri optimeerimise eesmärgiks on valmistada töötav 3D-MB, mille energiatihedus ning mahtuvus on vähemalt suurusjärgu võrra suuremad praegu kasutusel olevate akude omadest. Toimiva 3D-MB välja töötamiseks arendatakse ja uuritakse erinevaid mikroaku arhitektuure, neist sobiva väljavalimist ning optimeerimist lihtsustavad oluliselt teoreetilised, arvutisimulatsioonidega läbi viidavad uuringud, mis võimaldavad testida erinevaid 3D-MB arhitektuure, lahendada optimeerimisülesandeid elektroodide optimaalse geomeetria leidmiseks; optimeerida elektroodi pinda; uurida terve aku käitumist laadimisel-tühjakslaadimisel; optimeerida sobivaid mikroaku arhitektuure.
Meetodid makrotasandis, mida selliste uuringute läbiviimiseks kasutatakse on lõplike elementide meetod (LEM) ning mikrotasandil molekulaardünaamilise simulatsiooni meetod (MD). Simulatsioonide läbiviimiseks kasutatakse LEM-i puhul tarkvarapakette COMSOL Multiphysics ja Elmer ning MD puhul tarkvarapaketti dl_poly.

= '''Aktuaatorid, seadmed ja nende juhtimine''' =
==IPMC elektromehhaanilisi omadusi uuriva seadme juhtimine==

Töö eesmärgiks on koostada eksperimentaalne seade, mis mõõdab elektroaktiivsete polümeeride elektromehaanilisi omadusi. Materjale kasutatakse kunstlihastena erinevates rakendustes. Töö tulemuseks peab valmima moodul, mis võimaldab seadet juhtuda USB kaudu.

==IPMC täitureid kasutava autonoomse seadme konstrueerimine==

Eesmärgiks on nn kunstlihaeid kasutavate materjalide abil liikuvate autonoomsete seadmete konstrueerimine ning töö kirjeldamine. Valik ideid: "putukas", ratas, minipurilennuk, mikrohumanoid jne.

==Süsinik-polümeermaterjalidest täiturite juhtimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi. St. vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomine, nende mudelite kirjeldamine ning eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureus, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

==IPMC/süsinik polümeermaterjalidest energiakogujate uurimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi eesmärgiga vinkeskkonnas olevate vibratsioonidest saadav energia muundada elektrienergiaks. Töö kujutab endast vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomist, nende mudelite kirjeldamine nin eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureuse, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

== Lahedad ideed kunstlihaste rakendamiseks==
=== Ilmekas uksekoputi ===

Teha kunstlihastest ilmekas uksekoputi, vt. http://www.youtube.com/watch?feature=player_detailpage&v=-Kee7iyp_3U&list=TLC5Famb33RxE

= '''Signal and Image Processing''' ''(Signaali ja Pilditöötlus)'' =

''If you are interested in doing any of the following projects as your BSc project or if you would like to get more information please feel free to contact me via shb-AT-ut-DOT-ee''

For full list of project description please visit http://icv.ims.ut.ee/projectspage.html [[http://icv.ims.ut.ee/projectspage.html]]

= '''Robotics''' =
== Click here for [[student projects in robotics]] ==

= '''Partneritega seotud teemad''' =

==Kõrgkoolide õppekavade masinõppel põhinev analüüs==

Projekti eesmärgiks on arendada masinõppel põhinev tarkvara, mis suudaks automaatselt analüüsida ja kaardistada Tartu Ülikooli õppekavade ning nendes loetavate ainete sisu viisil, et oleks jooksvalt võimalik hinnata õppekvaliteeti ja selle vastavust tööturu reaalsetele vajadustele. '''Eriti sobilik tudengitele,''' kellel on lisaks erialasele huvile soov kokkupuutuda '''startup''' ja tehnoloogia ettevõttlusega.

'''Bakalaureuse- või magistritöö käigus loodav praktiline tarkvaralahendus:'''
* analüüsib õppekavade terviklikkust, erinevate moodulite ja õppeainete vaheliste seoste sidusust, vastavust õppekava ja mooduli üldeesmärkidele,
* analüüsib jooksvalt õppekavade vastavust tööturu vajadustele lähtuvalt töötajatele reaalselt esitatavatest kvalifikatsiooni nõuetest,
* annab õppejõududele ja programmijuhtidele infot võimalikest kattuvustest, puuduvatest eelteadmistest õppeainetele ja arenguvajadustest,
* võimaldab arendada ühismooduleid ja õppeaineid erinevate õppekavade vahel eeldusteadmiste lünkadeta ja kattuvusteta,
* võimaldab hinnata ja võrrelda juba olemasolevate ja veel loodavate õppekavade konkurentsivõimet teiste koolide sarnaste õppekavadega.

'''Antud lõputöö kontekstis olulised märksõnad on:'''
* suurandmed ja andmekaeve (big data & data mining)
* masinõppe algoritmid (machine learning)
* andmete visualiseerimine (data visualization)

Lõputööd juhendab Aleksander Tõnnisson, kes on teinud üle 40-ne investeeringu iduettevõtetesse.

==Mehhanoelektriliste andurite uurimine==

Töö eesmärgiks on eksperimentaalselt uurida erinevate mehaanilist liigutust elektriliseks muundavate materjalide omadusi. Töö hõlmab eksperimendi konstrueerimist ja arvutijuhitavate mõõtmiste teostamist LabVIEW keskkonnas. Sobib hästi arvutitehnika, füüsika ja materjaliteaduse tudengitele.

==Robotmannekeen rõivatööstusele==

Projekti eesmärgiks on arendada välja inimkeha kujuline mannekeeni alakeha rõivatööstusele kiirendamaks ning parendamaks disainerrõivaste väljatöötamist.
Projektis on vaja konstrueerida mehaanika sõlmed, realiseerida elektroonika juhtsõlmed, modeleerida ning luua algoritmid mannekeeni välispinna juhtimiseks ning arendada välja süsteemi kontroll tarkvara. Samuti on vaja arendada välja kasutajatarkvara. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

Projektil on ka konkreetne rakendus vt [http://www.fits.me www.fits.me]

==Puutetundlik sensor robotmannekeenile ==

Projekti eesmärgiks on arendada inimkeha kujuline mannekeenile puutetundlike "naha" välja arendamine.
Projektis on vaja uurida ja testida erinevaid sensoreid, Leida olulised mõõtevahemikud ja mõõtetäpsused vastavalt vajadusele rakenduses. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

= '''Õppetööga seotud''' =
==Sensori-anduri töö uurimine ja juhendmaterjali koostamine==

Töö eesmärgiks on eksperimentaalselt parametriseerida robootikas/automaatikas kasutatav sensor/täitur ning tulemuse põhjal koostada protokoll ja metoodika selle kasutamiseks.

== Juhendmaterjali koostamine koolirobootika tarbeks==

Töö eesmärgiks on koostada õpetajatele juhendmaterjale ja põnevaid tööülesandeid, aga samuti ülesandeid, mis aitavad lastel õppida füüsikat, matemaatikat, keemiat ja bioloogiat.
-->

=Üldine info bakalaureuse- ja magistritöö tegijatele=

Teil on kaks juhendajat. Eeldame, et te vähemalt kord nädalas võtate vähemalt ühe juhendajaga kontakti ja arutate läbi oma mured ja tegemised. Lisaks ootame tudengitelt aktiivset osavõttu kord nädalas toimuvast labori seminarist ja journal club'ist, kus harjutatakse avalikku esinemist, et kaitsmisel oleks lihtsam.

Töö esimene versioon peab olema esitatud hiljemalt 1. maiks. Hilinemiseks sobivad ainult dokumentaalselt tõestatavad meditsiinilised põhjused. Esimene version peab sisaldama:
# sissejuhatust, mis räägib, miks projekti tulemus on vajalik ja mida teised selles valdkonnas maailmas teinud on;
# projekti teoreetilisi/matemaatilisi/mudeli aluseid lahti kirjutatuna;
# tehtud tegevuse detailset kirjeldust (detaile pole kunagi liiga palju, delete on lihtsaim funktsioon, mida juhendaja teie kirjaliku töö ümber kirjutamisel :) teha saab);
# töö tulemusi, st kas mõõtmistulemusi või seadme töötava! prototüübi tehniline kirjeldust ja seadet ennast;
# hinnangut oma tööle, st töö tulemuste edasise arengu analüüsi, tulemuste analüüsi ja hinnangut töö tulemuse kvaliteedile.

'''Töö kaitsmisele lubamiseks on kohustuslik läbida laborisisene eelkaitsmine, vajadusel korduv'''. Eelkaitsmiste ajagraafik kuulutatakse välja igal aastal aprillis. Arvestada tuleb ajaliste piirangutega- Eelkaitsmisele õigeaegne registreerumine on tudengi kohustus.

Ionic Liquids

2018-05-30T08:55:06Z

Gajanee: /* Skills */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquids
* computational simulations for ionic liquids

== Primary contact ==
* [https://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==
* [[Ionic Liquids]]
* [[Biocompatible electroactive polymers]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Biocompatible electroactive polymers

2018-05-30T08:52:55Z

Gajanee: Created page with "Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditioonilised aktuaatorid ei ole pehmetes ja painduvates robotites rakendatav..."

Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditioonilised aktuaatorid ei ole pehmetes ja painduvates robotites rakendatavad, seega on antud rakenduse jaoks juba aastakümneid uuritud elektroaktiivseid polümeerseid täitureid (electroctive polymer - EAP). Nõudmised materjalile on kõrged: ideaalne aktuaator omab laia liigutusulatust juba madalal pingel, on kiire, kerge, vastupidav ning lihtsalt ja odavalt toodetav. Ühe EAPde rakendusena välja pakutud biomeditsiinilistes seadmetes (implantaadid, tehiskoed) on lisaks vajalik bioühilduvus. IMS Labori üks teadustöö eesmärke on välja töötada bioühilduv ioonne elektromehaaniline polümeerne täitur (ionic electroactive polymer - IEAP). Uuritav materjal koosneb juhtivpolümeersete või süsinikelektroodide vahele paigutatud biopolümeersest membraanist ning elektrolüüdina kasutatakse madala toksilisusega looduslikku päritolu ioonseid vedelikke. Bakalaureuse ja magistritöö teemasid on välja pakkuda projekti erinevates etappides:

* Biopolümeersete poorsete membraanide valmistamine erinevatel meetoditel ja uurimine, kuidas ioonsed vedelikud membraaniga interakteeruvad ning selles liiguvad.
* Juhtivpolümeersete elektroodide keemiline ja elektrokeemiline sadestamine biopolümeerse membraani pinnale. Saadud materjalide struktuur-omadused seoste uurimine.
* Ioonsete vedelike ja juhtivpolümeeride interaktsioonid elektriväljas
* Süsinikelektroodidega bioühilduve EAP valmistamine pihustusmeetodil: erinevate lähtematerjalide kombinatsioonide testimine.

Lisaks on välja pakkuda lõputöö teemasid EAP-des kasutatavete ioonsete vedelike alal:

* Ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetodeid kasutades

Ionic Liquids

2018-05-30T08:47:08Z

Gajanee: /* Student projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [https://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==
* [[Ionic Liquids]]
* [[Biocompatible electroactive polymers]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-30T08:45:39Z

Gajanee: /* Primary contact */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [https://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==
* [[Ioonsed vedelikud]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ioonsed vedelikud

2018-05-30T08:40:16Z

Gajanee: Created page with "Ioonsete vedelike alane teadustöö IMS Labis on suunatud rakendustele elektroaktiivsetes polümeerides (EAP). EAP-de üheks rakendusvaldkonnaks on erinevad meditsiiniseadmed..."

Ioonsete vedelike alane teadustöö IMS Labis on suunatud rakendustele elektroaktiivsetes polümeerides (EAP). EAP-de üheks rakendusvaldkonnaks on erinevad meditsiiniseadmed ning seega peavad kasutatavad materjalid olema bioühilduvad. Välja on pakkuda järgnevad teemad bakalaureuse või magistritöödeks:

* Madala toksilisusega ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetoditega
* Deep eutectic solvents (DES) kui alternatiivid ioonsetele vedelikele
* Ioonsete vedelike, nende segude ja DES-ide toksilisuse testimine

Ionic Liquids

2018-05-30T08:35:33Z

Gajanee: /* Student projects */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==
* [[Ioonsed vedelikud]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-30T08:14:33Z

Gajanee: /* Vision and goal */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.

Research in the IMS Lab focuses mostly on usage of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators and sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-30T08:12:06Z

Gajanee: /* Equipment */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===
All steps from materials development to device design and fabrication are covered:

* chemistry lab equipped for organic synthesis
* FT-IR spectrometer
* KF titrator
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* glove box

There is access in the faculty to NMR, DSC, TGA etc.

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-28T08:06:50Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau, D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-28T08:04:32Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454# Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-28T08:03:02Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386X Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862 Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454#support-information-section Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5# Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159 Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-28T08:02:11Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386XZaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* [https://pubs.acs.org/doi/abs/10.1021/acs.iecr.6b00862Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.]
* [https://onlinelibrary.wiley.com/doi/full/10.1002/ejic.201501454#support-information-sectionPohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.]
* [https://www.cambridge.org/core/journals/journal-of-materials-research/article/increased-conductivity-of-polymerized-ionic-liquids-through-the-use-of-a-nonpolymerizable-ionic-liquid-additive/86A1BB169CD6B7CA0FBEE67AD94A63F5#Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.]
* [https://www.tandfonline.com/doi/abs/10.1080/00397911.2012.745159Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.]

Ionic Liquids

2018-05-28T07:58:09Z

Gajanee: /* Selected Publications */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* [https://www.sciencedirect.com/science/article/pii/S016773221733386XZaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.]
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

Ionic Liquids

2018-05-28T07:51:52Z

Gajanee: /* Skills */

==Vision and goal ==

Ionic liquids are salts, which are liquid at ambient temperature. Ionic liquids have been in the focus of intense research for more than twenty years due to extraordinary physico-chemical properties like negligible vapour pressure, ionic conductivity, high thermal stability, broad liquidus range and interesting dissolution capabilities.
Research in IMS Lab mostly focuses on application of ionic liquids as electrolytes in electroactive polymers. Long time experiences in the field have helped us to determine the properties of ionic liquids responsible for high performance of electroactive polymer actuators or sensors. We synthesize and characterize ionic liquids and deep eutectic mixtures with aim to "tailor" the physico-chemical properties of the compounds to be suitable for specific applications. Bicompatibility and biodegradability of ionic liquids are of great importance in our research as potential applications for electroactive polymers include implantable or disposable medical devices, smart prosthesis, soft haptic devices and wearable electronics.

== Highlights ==

* The first time preparation of a fully biocompatible electroactive polymer based on biopolymers and biofriendly ionic liquids.
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===
We have experiences in working with different aspects of ionic liquids:
* synthesis and characterization of novel ionic liquids
* mixtures of ionic liquids and deep eutectic solvents
* polymerizable ionic liquids
* lanthanide containing ionic liquids
* CO2 capture using ionic liquids
* ionic liquids for tribology
* ionic liquids for synthesis of nanomaterials
* dissolution of biopolymers using ionic liquids
* toxicological testing of ionic liquis
* computational simulations for ionic liquids

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

Ionic Liquids

2018-05-28T07:38:22Z

Gajanee: /* Highlights */

Ionic Liquids

2018-05-28T07:29:21Z

Gajanee: /* Vision and goal */

Ionic Liquids

2018-05-28T06:52:21Z

Gajanee: /* Primary contact */

==Vision and goal ==

== Highlights ==

* ...
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===

== Primary contact ==
* [http://orcid.org/0000-0003-1928-5141 Kaija Põhako-Esko]
* [https://orcid.org/0000-0002-0183-1282 Alvo Aabloo]

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

Ionic Liquids

2018-05-23T11:56:24Z

Gajanee:

==Vision and goal ==

== Highlights ==

* ...
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===

== Primary contact ==
....

....

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===

* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

Ionic Liquids

2018-05-23T11:54:46Z

Gajanee: /* Specific information */

==Our vision and goal ==

== Highlights ==

* ...
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===

== Primary contact ==
....

....

== Student projects ==

== Porfolio ==

===Projects===

* Marie Sklodowska-Curie Individual Fellowhip "Development of biocompatible ionic electromechanically active polymer actuator/sensor" (1.09.2018-31.08.2020)
* MOBTP10 "Developmnt of biocompatible ionic electromechanically active polymer actuator (1.01.2017−31.12.2017)

=== Selected Publications ===
* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

Ionic Liquids

2018-05-23T11:54:03Z

Gajanee: /* Porfolio */

Ionic Liquids

2018-05-23T11:53:32Z

Gajanee: /* Projects */

Ionic Liquids

2018-05-23T11:47:22Z

Gajanee: /* Selected Publications */

==Our vision and goal ==

== Highlights ==

* ...
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===

== Primary contact ==
....

....

== Student projects ==

== Porfolio ==

===Projects===

=== Selected Publications ===
* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. ''J. Mol Liq.'' '''2017''', 248, 86-90.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. ''Ind. Eng. Chem. Res.'' '''2016''', 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. ''Eur. J. Inorg. Chem.'' '''2016''', 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. ''J. Mater. Res.'' '''2013''', 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. ''Synth. Commun.'' '''2013''', 43, 2846-2852.

=== Outreach ===

== Specific information ==

Ionic Liquids

2018-05-23T11:42:29Z

Gajanee: /* Selected Publications */

==Our vision and goal ==

== Highlights ==

* ...
* ...
* ...

== Capabilities ==

=== Equipment ===

=== Skills ===

== Primary contact ==
....

....

== Student projects ==

== Porfolio ==

===Projects===

=== Selected Publications ===
* Zaitsau,D.; Pohako-Esko, K.; Arlt, S.; Emelyanenko, V.; Schulz, P.; Wasserscheid, P.; Schulz, A. Thermodynamics of imidazolium based ionic liquids with cyano containing anions. J. Mol Liq.
* Pohako-Esko, K.; Bahlmann, M.; Schulz, P. S.; Wasserscheid, P. Chitosan containing supported ionic liquid phase materials for CO2 absorption. Ind. Eng. Chem. Res. 2016, 55, 7052-7059.
* Pohako-Esko, K.; Wehner, T.; Schulz, P. S.; Heinemann, F. W.; Mueller-Buschbaum, K.; Wasserscheid, P. Synthesis and properties of organic hexahalocerate(III) salts. Eur. J. Inorg. Chem. 2016, 9, 1333-1339.
* Pohako-Esko, K.; Timusk, M.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. Increased conductivity of polymerized ionic liquids by an non-polymerizable ionic liquid additive. J. Mater. Res. 2013, 28, 3086-3093.
* Põhako-Esko, K.; Taaber, T.; Saal, K.; Lõhmus, R.; Kink, I.; Mäeorg, U. New method for synthesis of methacrylate type polymerizable ionic liquids. Synth. Commun. 2013, 43, 2846-2852.

=== Outreach ===

== Specific information ==

Ionic Liquids

2018-05-23T11:35:12Z

Gajanee: Created page with "==Our vision and goal == == Highlights == * ... * ... * ... == Capabilities == === Equipment === === Skills === == Primary contact == .... .... == Student proje..."

Ioonsed vedelikud elektroatiivsete polümeeride jaoks

2018-05-04T08:02:29Z

Ioonsete vedelike alane teadustöö IMS Labis on suunatud rakendustele elektroaktiivsetes polümeerides (EAP). EAP-de üheks rakendusvaldkonnaks on erinevad meditsiiniseadmed ning seega peavad kasutatavad materjalid olema bioühilduvad. Välja on pakkuda järgnevad teemad bakalaureuse või magistritöödeks:
* Madala toksilisusega ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetoditega
* ''Deep eutectic solvents'' (DES) kui alternatiivid ioonsetele vedelikele
* Ioonsete vedelike, nende segude ja DES-ide toksilisuse testimine

Bioühilduvad elektroaktiivsed polümeerid

2018-05-04T07:53:22Z

Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditioonilised aktuaatorid ei ole pehmetes ja painduvates robotites rakendatavad, seega on antud rakenduse jaoks juba aastakümneid uuritud elektroaktiivseid polümeerseid täitureid (electroctive polymer - EAP). Nõudmised materjalile on kõrged: ideaalne aktuaator omab laia liigutusulatust juba madalal pingel, on kiire, kerge, vastupidav ning lihtsalt ja odavalt toodetav. Ühe EAPde rakendusena välja pakutud biomeditsiinilistes seadmetes (implantaadid, tehiskoed) on lisaks vajalik biosobivus. Antud projekti eesmärk on välja töötada biosobiv ioonne elektromehaaniline polümeerne täitur (ionic electroactive polymer - IEAP). Uuritav materjal koosneb juhtivpolümeersete või süsinikelektroodide vahele paigutatud biopolümeersest membraanist, elektrolüüdina kasutatakse madala toksilisusega looduslikku päritolu ioonseid vedelikke. Bakalaureuse ja magistritöö teemasid on välja pakkuda projekti erinevates etappides:

* Biopolümeersete poorsete membraanide valmistamine erinevatel meetoditel ja uurimine, kuidas ioonsed vedelikud membraaniga interakteeruvad ning selles liiguvad.
* Juhtivpolümeersete elektroodide keemiline ja elektrokeemiline sadestamine biopolümeerse membraani pinnale. Saadud materjalide struktuur-omadused seoste uurimine.
* Ioonsete vedelike ja juhtivpolümeeride interaktsioonid elektriväljas
* Süsinikelektroodidega bioühilduve EAP valmistamine pihustusmeetodil: erinevate lähtematerjalide kombinatsioonide testimine.

Lisaks on välja pakkuda lõputöö teemasid EAP-des kasutatavete ioonsete vedelike alal:
* Ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetodeid kasutades

Computational Materials

2018-05-04T07:29:54Z

Gajanee: /* Our vision, goal and what we do */

=IMS Simulations=
== Our vision, goal and what we do ==

[[File:multiscale.png|200px|thumb|right| Simulations heat transfer and mechanical stress of FCC metal in multiscale framework.]]
[[File:multiscale.png|200px|thumb|left| Simulations heat transfer and mechanical stress of FCC metal in multiscale framework.]]

Computer simulations are one of the most fascinating tools made available due to the development of modern computational technology. Simulations in physics, chemistry, materials science, engineering etc. allow us to obtain detailed information of the phenomena of interest and provide often complete 3D and time dependent information of quantities like electromagnetic fields, temperature, forces and mechanical stresses, deformations. Such information leads to deep insights and understanding of nature around us, opening ways to understand complex physical and chemical processes and to the development of novel technologies and applications.

The simulation activities conducted in the lab involve all levels from atomistic to macroscopic (DFT -> Molecular Dynamics -> Monter Carlo -> Finite Elements), including combinations of these methods i.e. multi scale simulations. The core capacity involves both, computational studies of materials and development of new methodology.

Some examples of applications:

* Mechanics
* CFD (turbulent & laminar)
* Heat transport
* Electric and magnetic fields
* Chemical reactions
* Acoustics
* Multiphysics combinations of these phenomena!

 
 
 

----
=== Image gallery ===

<gallery mode="packed-hover">
file:multiscale.png|''Some simulation results''
file:strainsfinal_facebook.jpg|"Shear strain field around nanovoid in MD and FEM"
file:tension2.gif|"Animation of stress and deformation in Cu during tensile testing"
file:multiscale.png
file:multiscale.png
file:multiscale.png
file:multiscale.png
file:multiscale.png
</gallery>

----

=== Tools we use ===
* Comsol Multiphysics [https://www.comsol.com/]
* LAMMPS [http://lammps.sandia.gov/]
* DEAL.II open source finite element library [http://dealii.org/]
* OpenFOAM CFD [https://www.openfoam.com/]
* FEMOCS (https://github.com/veskem/femocs)



== Research Projects ==
=== Ongoing Activities ===

* [[PUT 1372 - Mechanisms of vacuum arching in high electric field systems]]

=== Glory and Success ===
* [[PUT 57 - Multiscale simulations of dislocation generation in rf electric fields in the linear accelerator design (01.01.2013 - 31.12.2016)]]
* [[ETF 9216 - Development and optimization of 3D-microbatteries (01.01.2012-31.21.2015)]]

=== Student projects ===
* [[Materjalidefektide simuleerimine kõrgetes elektriväljades]]
* [[Järgmise generatsiooni bioreaktorid]]
* [[Ehitiste konstruktsioonielementide multiskaala mudelite arendamine]]



== Members ==

IMS Simulations Tartu group

* Vahur Zadin
* Tarmo Tamm
* Simon Vigonski
* Heiki Kasemägi
* Priit Priimägi
* Kristian Kuppart
* Faiza Summer
* Robert Aare
* Ats Aasmaa
* (Mihkel Veske, in Helsinki University)

Friends and collaborators

*Flyura Djurabekova (Helsinki University)
*Ville Jansson (Helsinki University)
*Walter Wuench (CERN)
*Daniel Brandell (Uppsala University)



==Publications==
(All references in Harvard style from Google Scholar)

# [[Data sets of migration barriers for atomistic Kinetic Monte Carlo simulations of Cu self-diffusion via first nearest neighbour atomic jumps. Data in Brief, 17, pp.739-743|Baibuz, E., Vigonski, S., Lahtinen, J., Zhao, J., Jansson, V., Zadin, V. and Djurabekova, F., 2018. Data sets of migration barriers for atomistic Kinetic Monte Carlo simulations of Cu self-diffusion via first nearest neighbour atomic jumps. Data in Brief, 17, pp.739-743]]
# Zadin, V., Veske, M., Vigonski, S., Jansson, V., Muszynski, J., Parviainen, S., Aabloo, A. and Djurabekova, F., 2018. Simulations of surface stress effects in nanoscale single crystals. Modelling and Simulation in Materials Science and Engineering.
# Metspalu, T., Jansson, V., Zadin, V., Avchaciov, K., Nordlund, K., Aabloo, A. and Djurabekova, F., 2018. Cu self-sputtering MD simulations for 0.1–5 keV ions at elevated temperatures. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 415, pp.31-40.
# Vigonski, S., Jansson, V., Vlassov, S., Polyakov, B., Baibuz, E., Oras, S., Aabloo, A., Djurabekova, F. and Zadin, V., 2017. Au nanowire junction breakup through surface atom diffusion. Nanotechnology, 29(1), p.015704.
#Kyritsakis, A., Veske, M., Eimre, K., Zadin, V. and Djurabekova, F., 2017. Thermal runaway and evaporation of metal nano-tips during intense electron emission. arXiv preprint arXiv:1710.00050.
#Priimägi, P., Kasemägi, H., Aabloo, A., Brandell, D. and Zadin, V., 2017. Thermal Simulations of Polymer Electrolyte 3D Li-Microbatteries. Electrochimica Acta, 244, pp.129-138.
#Baibuz, E., Vigonski, S., Lahtinen, J., Zhao, J., Jansson, V., Zadin, V. and Djurabekova, F., 2017. Migration barriers for surface diffusion on a rigid lattice: challenges and solutions. arXiv preprint arXiv:1707.05765.
#Veske, M., Kyritsakis, A., Eimre, K., Zadin, V., Aabloo, A. and Djurabekova, F., 2017. Dynamic coupling of a finite element solver to large-scale atomistic simulations. arXiv preprint arXiv:1706.09661.
#Yanagisawa, H., Zadin, V., Kunze, K., Hafner, C., Aabloo, A., Kim, D.E., Kling, M.F., Djurabekova, F., Osterwalder, J. and Wuensch, W., 2016. Laser-induced asymmetric faceting and growth of a nano-protrusion on a tungsten tip. APL Photonics, 1(9), p.091305.
#Mets, M., Antsov, M., Zadin, V., Dorogin, L.M., Aabloo, A., Polyakov, B., Lõhmus, R. and Vlassov, S., 2016. Structural factor in bending testing of fivefold twinned nanowires revealed by finite element analysis. Physica Scripta, 91(11), p.115701.
#CLIC, T., Boland, M.J., Felzmann, U., Giansiracusa, P.J., Lucas, T.G., Rassool, R.P., Balazs, C., Charles, T.K., Afanaciev, K., Emeliantchik, I. and Ignatenko, A., 2016. Updated baseline for a staged Compact Linear Collider. arXiv preprint arXiv:1608.07537.
#Priimägi, P., Brandell, D., Srivastav, S., Aabloo, A., Kasemägi, H. and Zadin, V., 2016. Optimizing the design of 3D-pillar microbatteries using finite element modelling. Electrochimica Acta, 209, pp.138-148.
#Veske, M., Kyritsakis, A., Djurabekova, F., Aare, R., Eimre, K. and Zadin, V., 2016, July. Atomistic modeling of metal surfaces under high electric fields: Direct coupling of electric fields to the atomistic simulations. In Vacuum Nanoelectronics Conference (IVNC), 2016 29th International (pp. 1-2). IEEE.
#Veske, M., Parviainen, S., Zadin, V., Aabloo, A. and Djurabekova, F., 2016. Electrodynamics—molecular dynamics simulations of the stability of Cu nanotips under high electric field. Journal of Physics D: Applied Physics, 49(21), p.215301.
#Vigonski, S., Veske, M., Aabloo, A., Djurabekova, F. and Zadin, V., 2015. Verification of a multiscale surface stress model near voids in copper under the load induced by external high electric field. Applied Mathematics and Computation, 267, pp.476-486.
#Zadin, V., Kasemägi, H., Valdna, V., Vigonski, S., Veske, M. and Aabloo, A., 2015. Application of multiphysics and multiscale simulations to optimize industrial wood drying kilns. Applied Mathematics and Computation, 267, pp.465-475.
#Eimre, K., Parviainen, S., Aabloo, A., Djurabekova, F. and Zadin, V., 2015. Application of the general thermal field model to simulate the behaviour of nanoscale Cu field emitters. Journal of Applied Physics, 118(3), p.033303.
#Vigonski, S., Djurabekova, F., Veske, M., Aabloo, A. and Zadin, V., 2015. Molecular dynamics simulations of near-surface Fe precipitates in Cu under high electric fields. Modelling and Simulation in Materials Science and Engineering, 23(2), p.025009.
#Zadin, V., Krasheninnikov, A.V., Djurabekova, F. and Nordlund, K., 2015. Simulations of electromechanical shape transformations of Au nanoparticles. physica status solidi (b), 252(1), pp.144-148.
#Zadin, V., Pohjonen, A., Aabloo, A., Nordlund, K. and Djurabekova, F., 2014. Electrostatic-elastoplastic simulations of copper surface under high electric fields. Physical Review Special Topics-Accelerators and Beams, 17(10), p.103501.
#Zadin, V., Brandell, D., Kasemägi, H., Lellep, J. and Aabloo, A., 2013. Designing the 3D-microbattery geometry using the level-set method. Journal of Power Sources, 244, pp.417-428.



==Defended theses==

=== Masters Theses ===
* Kristjan Eimre
* Kristian Kuppart
* Robert Aare
* ....



=== Bachelor's theses ===

* [[Kristjan Eimre - title]]
* [[Kristian Kuppart - title]]
* ....



 
 
 

=IMS Materials=
== Our vision, goal and what we do ==

Siia tuleb sissejuhatav tekst ja sellele järgneb alajaotus teemade kaupa

* Electroactive polymers (Tarmo, Urmas)
* Ionic liquids (Kaija)
* Microfabrication (Anna-Liisa)
* Energy harvest and flow capacitors (Janno)
* Indrek?

=== Tools we use ===

All steps from materials development to device design and fabrication are covered:
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* FT-IR spectrometer
* KF titrator
* chemistry lab equipped for organic synthesis
* glove box
* .....



== Research Projects ==
=== Ongoing Activities ===
Igaüks, kellel on projekt, võiks hoolitseda selle eest, et see siin kajastuks

* [[IUT 2024 - Stimuli-Responsive Smart Polymer Composite Materials and their Applications in Lab-on chip Devices and in Robotics]]

=== Glory and Success ===
* [[MOBTP 10 - Developmnt of biocompatible ionic electromechanically active polymer actuator (01.01.2017 - 31.12.2017)]]
* ....

=== Student projects ===
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]
* ....



== Members ==

IMS Materials Tartu group

* Tarmo Tamm
* Urmas Johanson
* Kaija Põhako-Esko
* Anna-Liisa Peikolainen
* Janno Torop
* Indrek Must

PhD students (igaüks hoolitseb, et tema omad kirjas oleks)
* Fred Elhi
* Pille Rinne
* Karl Karu
* Kadi-Anne Küppar

Friends and collaborators



==Publications==


==Defended theses==

=== PhD Theses ===
* .....

=== Master's Theses ===
* Kadi-Anne Küppar "Preparation and characterization of biopolymer membranes for electroactive polymers" 2017
* ....

=== Bachelor's theses ===
* ....

Computational Materials

2018-05-04T07:06:53Z

Gajanee: /* IMS Simulations */

=IMS Simulations=
== Our vision, goal and what we do ==

[[File:multiscale.png|200px|thumb|right| Simulations heat transfer and mechanical stress of FCC metal in multiscale framework.]]
[[File:multiscale.png|200px|thumb|left| Simulations heat transfer and mechanical stress of FCC metal in multiscale framework.]]

Computer simulations are one of the most fascinating tools made available due to the development of modern computational technology. Simulations in physics, chemistry, materials science, engineering etc. allow us to obtain detailed information of the phenomena of interest and provide often complete 3D and time dependent information of quantities like electromagnetic fields, temperature, forces and mechanical stresses, deformations. Such information leads to deep insights and understanding of nature around us, opening ways to understand complex physical and chemical processes and to the development of novel technologies and applications.

The simulation activities conducted in the lab involve all levels from atomistic to macroscopic (DFT -> Molecular Dynamics -> Monter Carlo -> Finite Elements), including combinations of these methods i.e. multi scale simulations. The core capacity involves both, computational studies of materials and development of new methodology.

Some examples of applications:

* Mechanics
* CFD (turbulent & laminar)
* Heat transport
* Electric and magnetic fields
* Chemical reactions
* Acoustics
* Multiphysics combinations of these phenomena!

 
 
 

----
=== Image gallery ===

<gallery mode="packed-hover">
file:multiscale.png|''Some simulation results''
file:strainsfinal_facebook.jpg|"Shear strain field around nanovoid in MD and FEM"
file:tension2.gif|"Animation of stress and deformation in Cu during tensile testing"
file:multiscale.png
file:multiscale.png
file:multiscale.png
file:multiscale.png
file:multiscale.png
</gallery>

----

=== Tools we use ===
* Comsol Multiphysics [https://www.comsol.com/]
* LAMMPS [http://lammps.sandia.gov/]
* DEAL.II open source finite element library [http://dealii.org/]
* OpenFOAM CFD [https://www.openfoam.com/]
* FEMOCS (https://github.com/veskem/femocs)



== Research Projects ==
=== Ongoing Activities ===

* [[PUT 1372 - Mechanisms of vacuum arching in high electric field systems]]

=== Glory and Success ===
* [[PUT 57 - Multiscale simulations of dislocation generation in rf electric fields in the linear accelerator design (01.01.2013 - 31.12.2016)]]
* [[ETF 9216 - Development and optimization of 3D-microbatteries (01.01.2012-31.21.2015)]]

=== Student projects ===
* [[Materjalidefektide simuleerimine kõrgetes elektriväljades]]
* [[Järgmise generatsiooni bioreaktorid]]
* [[Ehitiste konstruktsioonielementide multiskaala mudelite arendamine]]



== Members ==

IMS Simulations Tartu group

* Vahur Zadin
* Tarmo Tamm
* Simon Vigonski
* Heiki Kasemägi
* Priit Priimägi
* Kristian Kuppart
* Faiza Summer
* Robert Aare
* Ats Aasmaa
* (Mihkel Veske, in Helsinki University)

Friends and collaborators

*Flyura Djurabekova (Helsinki University)
*Ville Jansson (Helsinki University)
*Walter Wuench (CERN)
*Daniel Brandell (Uppsala University)



==Publications==
(All references in Harvard style from Google Scholar)

# [[Data sets of migration barriers for atomistic Kinetic Monte Carlo simulations of Cu self-diffusion via first nearest neighbour atomic jumps. Data in Brief, 17, pp.739-743|Baibuz, E., Vigonski, S., Lahtinen, J., Zhao, J., Jansson, V., Zadin, V. and Djurabekova, F., 2018. Data sets of migration barriers for atomistic Kinetic Monte Carlo simulations of Cu self-diffusion via first nearest neighbour atomic jumps. Data in Brief, 17, pp.739-743]]
# Zadin, V., Veske, M., Vigonski, S., Jansson, V., Muszynski, J., Parviainen, S., Aabloo, A. and Djurabekova, F., 2018. Simulations of surface stress effects in nanoscale single crystals. Modelling and Simulation in Materials Science and Engineering.
# Metspalu, T., Jansson, V., Zadin, V., Avchaciov, K., Nordlund, K., Aabloo, A. and Djurabekova, F., 2018. Cu self-sputtering MD simulations for 0.1–5 keV ions at elevated temperatures. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 415, pp.31-40.
# Vigonski, S., Jansson, V., Vlassov, S., Polyakov, B., Baibuz, E., Oras, S., Aabloo, A., Djurabekova, F. and Zadin, V., 2017. Au nanowire junction breakup through surface atom diffusion. Nanotechnology, 29(1), p.015704.
#Kyritsakis, A., Veske, M., Eimre, K., Zadin, V. and Djurabekova, F., 2017. Thermal runaway and evaporation of metal nano-tips during intense electron emission. arXiv preprint arXiv:1710.00050.
#Priimägi, P., Kasemägi, H., Aabloo, A., Brandell, D. and Zadin, V., 2017. Thermal Simulations of Polymer Electrolyte 3D Li-Microbatteries. Electrochimica Acta, 244, pp.129-138.
#Baibuz, E., Vigonski, S., Lahtinen, J., Zhao, J., Jansson, V., Zadin, V. and Djurabekova, F., 2017. Migration barriers for surface diffusion on a rigid lattice: challenges and solutions. arXiv preprint arXiv:1707.05765.
#Veske, M., Kyritsakis, A., Eimre, K., Zadin, V., Aabloo, A. and Djurabekova, F., 2017. Dynamic coupling of a finite element solver to large-scale atomistic simulations. arXiv preprint arXiv:1706.09661.
#Yanagisawa, H., Zadin, V., Kunze, K., Hafner, C., Aabloo, A., Kim, D.E., Kling, M.F., Djurabekova, F., Osterwalder, J. and Wuensch, W., 2016. Laser-induced asymmetric faceting and growth of a nano-protrusion on a tungsten tip. APL Photonics, 1(9), p.091305.
#Mets, M., Antsov, M., Zadin, V., Dorogin, L.M., Aabloo, A., Polyakov, B., Lõhmus, R. and Vlassov, S., 2016. Structural factor in bending testing of fivefold twinned nanowires revealed by finite element analysis. Physica Scripta, 91(11), p.115701.
#CLIC, T., Boland, M.J., Felzmann, U., Giansiracusa, P.J., Lucas, T.G., Rassool, R.P., Balazs, C., Charles, T.K., Afanaciev, K., Emeliantchik, I. and Ignatenko, A., 2016. Updated baseline for a staged Compact Linear Collider. arXiv preprint arXiv:1608.07537.
#Priimägi, P., Brandell, D., Srivastav, S., Aabloo, A., Kasemägi, H. and Zadin, V., 2016. Optimizing the design of 3D-pillar microbatteries using finite element modelling. Electrochimica Acta, 209, pp.138-148.
#Veske, M., Kyritsakis, A., Djurabekova, F., Aare, R., Eimre, K. and Zadin, V., 2016, July. Atomistic modeling of metal surfaces under high electric fields: Direct coupling of electric fields to the atomistic simulations. In Vacuum Nanoelectronics Conference (IVNC), 2016 29th International (pp. 1-2). IEEE.
#Veske, M., Parviainen, S., Zadin, V., Aabloo, A. and Djurabekova, F., 2016. Electrodynamics—molecular dynamics simulations of the stability of Cu nanotips under high electric field. Journal of Physics D: Applied Physics, 49(21), p.215301.
#Vigonski, S., Veske, M., Aabloo, A., Djurabekova, F. and Zadin, V., 2015. Verification of a multiscale surface stress model near voids in copper under the load induced by external high electric field. Applied Mathematics and Computation, 267, pp.476-486.
#Zadin, V., Kasemägi, H., Valdna, V., Vigonski, S., Veske, M. and Aabloo, A., 2015. Application of multiphysics and multiscale simulations to optimize industrial wood drying kilns. Applied Mathematics and Computation, 267, pp.465-475.
#Eimre, K., Parviainen, S., Aabloo, A., Djurabekova, F. and Zadin, V., 2015. Application of the general thermal field model to simulate the behaviour of nanoscale Cu field emitters. Journal of Applied Physics, 118(3), p.033303.
#Vigonski, S., Djurabekova, F., Veske, M., Aabloo, A. and Zadin, V., 2015. Molecular dynamics simulations of near-surface Fe precipitates in Cu under high electric fields. Modelling and Simulation in Materials Science and Engineering, 23(2), p.025009.
#Zadin, V., Krasheninnikov, A.V., Djurabekova, F. and Nordlund, K., 2015. Simulations of electromechanical shape transformations of Au nanoparticles. physica status solidi (b), 252(1), pp.144-148.
#Zadin, V., Pohjonen, A., Aabloo, A., Nordlund, K. and Djurabekova, F., 2014. Electrostatic-elastoplastic simulations of copper surface under high electric fields. Physical Review Special Topics-Accelerators and Beams, 17(10), p.103501.
#Zadin, V., Brandell, D., Kasemägi, H., Lellep, J. and Aabloo, A., 2013. Designing the 3D-microbattery geometry using the level-set method. Journal of Power Sources, 244, pp.417-428.



==Defended theses==

=== Masters Theses ===
* Kristjan Eimre
* Kristian Kuppart
* Robert Aare
* ....



=== Bachelor's theses ===

* [[Kristjan Eimre - title]]
* [[Kristian Kuppart - title]]
* ....



 
 
 

=IMS Materials=
== Our vision, goal and what we do ==

Siia tuleb sissejuhatav tekst ja sellele järgneb alajaotus teemade kaupa

* Electroactive polymers (Tarmo, Urmas)
* Ionic liquids (Kaija)
* Microfabrication (Anna-Liisa)

=== Tools we use ===

All steps from materials development to device design and fabrication are covered:
* potentiostats/galvanostats/frequenzy analyzers
* SEM equipped with EDX
* FT-IR spectrometer
* KF titrator
* chemistry lab equipped for organic synthesis
* glove box
* .....



== Research Projects ==
=== Ongoing Activities ===
Igaüks, kellel on projekt, võiks hoolitseda selle eest, et see siin kajastuks

* [[IUT 2024 - Stimuli-Responsive Smart Polymer Composite Materials and their Applications in Lab-on chip Devices and in Robotics]]

=== Glory and Success ===
* [[MOBTP 10 - Developmnt of biocompatible ionic electromechanically active polymer actuator (01.01.2017 - 31.12.2017)]]
* ....

=== Student projects ===
* [[Ioonsed vedelikud elektroatiivsete polümeeride jaoks]]
* [[Bioühilduvad elektroaktiivsed polümeerid]]
* ....



== Members ==

IMS Materials Tartu group

* Tarmo Tamm
* Urmas Johanson
* Kaija Põhako-Esko
* Anna-Liisa Peikolainen
* Janno Torop
* Indrek Must

PhD students (igaüks hoolitseb, et tema omad kirjas oleks)
* Fred Elhi
* Pille Rinne
* Karl Karu
* Kadi-Anne Küppar

Friends and collaborators



==Publications==


==Defended theses==

=== PhD Theses ===
* .....

=== Master's Theses ===
* Kadi-Anne Küppar "Preparation and characterization of biopolymer membranes for electroactive polymers" 2017
* ....

=== Bachelor's theses ===
* ....

User:Gajanee

2016-10-18T08:17:59Z

Gajanee: Created page with "==Kaija Põhako-Esko== 400px * Phone: (+372) 737 4823 * Mobile: (+372) 5340 0450 * E-mail: kaija.pohako[ät]ut.ee * Postal address: ::::IMS Lab ::::..."

==Kaija Põhako-Esko==

[[File:Kaija.jpg|400px]]

* Phone: (+372) 737 4823

* Mobile: (+372) 5340 0450

* E-mail: kaija.pohako[ät]ut.ee

* Postal address:

::::IMS Lab

::::Institute of Technology

::::University of Tartu

::::Nooruse 1

::::50411 Tartu

::::Estonia

People

2016-10-18T08:15:21Z

Gajanee: /* Staff */

File:Kaija.jpg

2016-10-18T08:12:40Z

Gajanee:

Student projects

2016-10-04T07:24:48Z

Gajanee: /* Üldine info bakalaureuse- ja magistritöö tegijatele */

[[Image:IMS poster.png|300px|right]]

''Siin on mõned tegemised, mide meie uurimisgrupi juures on võimalik teha. Tegemist pole lõpliku nimekirjaga ning head tegijad on alati oodatud huvitavate ideedega. Kõikidest teemadest on võimalik edasi minna kuni PhD kaitsmiseni.''
''Tegijad, kes teevad oma töö hindele A, saavad ka väärilise töötasu.'' ''Huvi korral [[User:Alvo#Contacts|võta ühendust]]''. Mõnede teemade kirjeldused on inglise keeles. Nende teemade juhendajateks on külalisteadlased ja -õppejõud.


= '''Eksperimentaalne materjaliteadus''' =

==Biorakendusteks sobiv "kunstlihas"==

Bioinspireeritud robootika on tänapäeva inseneritehnoloogia ja teaduse peamisi arengusuundi. Traditioonilised aktuaatorid ei ole pehmetes ja painduvates robotites rakendatavad, seega on antud rakenduse jaoks juba aastakümneid uuritud elektroaktiivseid polümeerseid täitureid (electroctive polymer - EAP). Nõudmised materjalile on kõrged: ideaalne aktuaator omab laia liigutusulatust juba madalal pingel, on kiire, kerge, vastupidav ning lihtsalt ja odavalt toodetav. Ühe EAPde rakendusena välja pakutud biomeditsiinilistes seadmetes (implantaadid, tehiskoed) on lisaks vajalik biosobivus. Antud projekti eesmärk on välja töötada biosobiv ioonne elektromehaaniline polümeerne täitur (ionic electroactive polymer - IEAP). Uuritav materjal koosneb juhtivpolümeersete elektroodide vahele paigutatud biopolümeersest membraanist, elektrolüüdina kasutatakse madala toksilisusega looduslikku päritolu ioonseid vedelikke. Bakalaureuse ja magistritöö teemasid on välja pakkuda projekti erinevates etappides:
* Ioonsete vedelike süntees ja karakteriseerimine
* Ioonsete vedelike segude uurimine nii eksperimentaalselt kui arvutuskeemia meetodeid kasutades
* Biopolümeersete poorsete membraanide valmistamine erinevatel meetoditel ja uurimine, kuidas ioonsed vedelikud membraaniga interakteeruvad ning selles liiguvad
* Juhtivpolümeersete elektroodide keemiline ja elektrokeemiline sadestamine biopolümeerse membraani pinnale
* Ioonsete vedelike ja juhtivpolümeeride interaktsioonid elektriväljas

== Süsinikelektroodidega polümeersed täiturid==

Kunstlihaseid ehk elektroaktiivseid polümeerseid täitureid on väga palju erinevaid. Nanopoorsest süsinikust elektroodidega ioonsed täiturid töötavad madalpingel ning neil on mitmed eelised kasutamiseks mikroseadmetes ja meditsiinis. Hetkel on uurimisel kaks suunda. Esimese eesmärk on arendada kunstlihasetes kasutatavaid ioonvedelik-süsinik-polümeer komposiite, kasutades selleks erinevaid süsinikmaterjale (süsinikaerogeeli, karbiidset süsinikku, süsiniknanotorusid jpt), ioonseid vedelikke, polümeere. Teine suund keskendub uute kunstlihase valmistamise tehnoloogiate rakendamisele. Uurime materjalide omadusi ja toimimismehhanisme, et kasutada neid aktuaatorite ning sensoritena. Bakalaureuse- ja magistritööks on teemasid mõlemast suunast:
* uut tüüpi nanomaterjali kasutamine täituri elektroodina
* süsinik-kserogeeli valmistamine ja struktuur-omadus seoste uurimine
* täituri valmistamine vurrkatmise meetodil (spin-coating)

==Kunstlihased kosmoserakendustes==

Meie poolt valmistatavad materjalid on kerged ning juhitavad madalate elektripingetega. Seetõttu pakuvad nad huvi kosmosetehnoloogia seadmete valmistajatele.
Töö eesmärgiks on uurida kiirguse, temperatuuri jpt kosmoses materjalidele mõjuvate kahjustavate toimete mõju.

==Juhtivpolümeeridel põhinevate mitmekihiliste kunstlihaste valmistamine ja iseloomustamine==

Kunstlihased, sensorid ja energiahõiveseadmed on elektritjuhtivate orgaaniliste polümeeride uudsemateks ja põnevamateks arengusuundadeks. Neid loodetakse kasutada meditsiinis, robootikas, kosmose- ja militaartööstuses. Enne laiaulatuslikku kasutuselevõttu on siiski vaja veel teha hulk arendustööd. Mitmekihilise disain loob eeldused juhtivpolümeerse materjali paremaks kontrollimiseks ning tema omaduste parandamiseks. TÜ IMS laboris on välja töötatud uudsed sünteesimeetodid metallivabade kunstlihaste valmistamiseks. Senistel lihtsa ühekihilise struktuuriga materjalidel on mitmeid puudusi (juhtuvuse langus, tundlikus väliskeskkonna mõjudele). Aktuatsiooni tekitavale polümeerikihile vastupidise ioonliikuvusega kihtide lisamine loob eelduse neid puudusi vältida.

==Design of actuator performance ==
(EAP development, technology), Master or bachelor student
The focus of actuator research mainly based on actuator preparation in view of new devices. Carbide derived carbon materials is applied as actuator and conductive material to deposit conducting polymer on it. The interaction between these materials are object of the actuator studies with main goal to optimize actuator strain and stress. Improvement of actuator devices over additional chemical modification (hydrophobic or hydrophilic coatings) are included in the new design of actuator performance.

==Süsinikelektroodidega täiturmaterjali tööstusliku tootmise ettevalmistamine==

Projekti sisuks on välja töötada materjal ja metoodika kuidas valmistada süsinikelektroodidega täitureid tööstuslikke protsesse kasutades. Töö laiem eesmärk on selliste materjalide masstootmine.

==Biokütuseelement==

Biokütuseelement on bioreaktor, mis muundab orgaaniliste ühendite keemiliste sidemete energia elektrienergiaks. Näiteks glükoosil ja hapnikul töötavad biokütuseelemendid, mis on võimelised energiat korjama erinevates bioloogilistest vedelikest, on paljulubavad seadmed rakendamiseks energiaallikatena mitmesugustes bioelektrilistes implantaatides nagu insuliinipumbad, ravimidosaatorid, närvistimulaatorid, südamestimulaatorid. Antud projekt tegeleb uudse elektroodimaterjali väljatöötamisega biokütuseelemendi jaoks.

= '''Arvutieksperimendid ja materjalide simuleerimine''' =

==Materjalidefektide simuleerimine kõrgsageduslikes elektriväljades==
[[Image:Reklaamposter.png|right|thumb|400px]]
Nutikas tudeng, kes sa tunned huvi tänapäeva tippteaduse vastu ning soovid oma lõputööd teha CERN-iga seotud teemal ning tegutsedes CERN-is! Võta ühendust ning osale uue CERN-is baseeruva kiirendi väljatöötamisel! '''(Doktoritöö võimalus!)'''

Kompaktne lineaarpõrguti (CLIC) on CERN-is arendatav uue põlvkonna lineaarkiirendi, kus osakeste kiirendamine toimub sirgjoonelistel trajektooridel. Planeeritav seade on 50 km pikk ning sellega jõutakse energiateni 0.5 TeV - 5 TeV. Saavutamaks sellist energiat, kasutatakse kiirendavat elektrivälja, mis ulatub 100-150 MV/m. Sellistes kõrgetes elektriväljades avaldub olulise probleemina aga sage elektriliste läbilöökide tekkimine kiirendi elektroodidel.

Läbilöögid avalduvad vaakumkaartena (kaarlahendus vaakumis), ning üldiselt eeldatakse, et vaakumkaar algab elektrivälja võimendavate nanoskaalas olevatelt nõelasarnastelt pinnadefektidelt, nende pinnadefektide tekkemehhanism on ebaselge. '''Elektriliste läbilöökide kahandamine alla kriitilise piiri on keskse tähtsusega probleemiks CLIC-i ehitamisel!'''

Üks lubavamaid meetodeid kiirendi struktuuri parandamiseks on uute materjalide leidmine, mis suudavad taluda kõrgeid elektrivälju ning kiireid elektriväljade muutusi. Võtmeprobleemiks uute materjalide leidmisel on arusaamine füüsikalistest protsessidest, mis toimuvad materjalis läbilöögi eel ning ajal. Uurimustöös kasutatakse erinevaid arvutusmeetodeid, nagu '''molekulaardünaamika, lõplike elementide meetod ja kineetiline Monte-Carlo''', selgitamaks elektriliste läbilöökideni viivate pinnadefektide tekkepõhjuseid. Töös vajalike aruvutisimulatsioonide läbiviimine tähendab, et suures plaanis kasutatakse nn. '''„multiscale“ simulatsioone''', millega kaetakse materjalide simuleerimine alates atomistlikust skaalast kuni makroskaalani.

Lineaarkiirendi rakendusvaldkondadeks on näiteks standardmudeli järgne füüsika (physics beyond the standard model), Higgsi bosoni täppismõõtmised ning meditsiinilised valdkonnad, nagu näiteks vähiravi.

==Kunstlihaste materjalide uurimine erinevate arvutisimulatsioonimeetodite abil==

* Tegemist on materjaliga, mida välise elektriväljaga on võimalik panna kuju muutma: painduma, punduma, kokku tõmbuma - nagu teeb reaalne lihas
* kunstlihase materjal võib ka reageerida välisele mehaanilisele kujumuutusele elektrilise signaaliga
* kunstlihas tegutseb hääletult, olles ise mõõtmetelt väga väike
* kunstlihase materjalidena uuritakse selliseid "hitte" nagu grafeen ja ioonvedelik
* arvutisimulatsioonid viivad sind materjali "sisse", võimaldades näha seda, mis katses jääb varju, anda infot toimuvate protsesside kohta ja näpunäiteid materjalide parendamiseks
* tahad teda, kuidas liigutab 2 cm pikkune riba kunstlihast? võta lõplike lementide meetod ja sa näed ära pinged ja deformatsioonid kujumuutmisel
* tahad teada, kuidas elektroodide kuju muutmine mõjutab liitiumioonaku mahtuvust - seda, kui kaua sinu elektriauto mööda Tartu-Tallinna maanteed suudaks kihutada? võta lõplike elementide meetod ja sa saad välja arvutada aku tühjenemise kiiruse sinu elektriauto toitmisel
* tahad teada, kuidas liiguvad ja mõjutavad üksteist aatomid ja molekulid kunstlihases ja liitiumioonaku elektroodides ning elektrolüüdis? võta molekulaardünaamiline simulatsioon ja sa saad siseneda maailma, mis on 10000 korda väiksem sinu juuksekarva läbimõõdust
* tahad virtuaalselt istuda iga aatomi peal ja näha, kuidas ühe aatomi elektronpilv lööb teise oma segamini? võta kvantkeemiline molekulaardünaamika ja sinu sõit lainefunktsioonide harjadel on pöörasem kui Ristna neemel Katja ajal.

==Liitium-ioon akude arhitektuuri optimeerimine arvutisimulatsioonide abil==

Kaasaskantav mikroakutoide on oluliseks faktoriks paljudes arenevates tehnoloogiasuundades, kuna mikroelektroonika mõõtmete vähenemine on jätnud kaugele seljataha väikesemõõduliste vooluallikate arengu. Sobivate kaasaskantavate vooluallikate vähene energiamahtuvus on saamas takistuseks mitmete tehnoloogiasuundade nagu kaasaskantavate arvutusseadmete (Weareable Computing Technology e. WCT), mikroelektromehaaniliste seadmete (MEMS), biomeditsiiniliste mikromasinate arengus. Üheks võtmeprobleemiks selliste seadmete edukaks toimimiseks on nende varustamine vooluallikatega, mis ühelt küljelt tagavad seadme piisava energiahulgaga varustamise ning teiselt küljelt, on võimalikult väikesemõõduised ning kergekaalulised. Sellise konfiguratsiooni juures tulevad ilmsiks olemasolevate, olemuselt kahemõõtmeliste (2D) liitium-ioonakude puudused – nii väikeste ruum- ja pindalade puhul ei ole võimalik saavutada piisavaid energiatihedusi. Seda probleemi võimaldab lahendada 3D mikroakude (MB) kasutusele võtmine.
Liitiumioonakude arhitektuuri optimeerimise eesmärgiks on valmistada töötav 3D-MB, mille energiatihedus ning mahtuvus on vähemalt suurusjärgu võrra suuremad praegu kasutusel olevate akude omadest. Toimiva 3D-MB välja töötamiseks arendatakse ja uuritakse erinevaid mikroaku arhitektuure, neist sobiva väljavalimist ning optimeerimist lihtsustavad oluliselt teoreetilised, arvutisimulatsioonidega läbi viidavad uuringud, mis võimaldavad testida erinevaid 3D-MB arhitektuure, lahendada optimeerimisülesandeid elektroodide optimaalse geomeetria leidmiseks; optimeerida elektroodi pinda; uurida terve aku käitumist laadimisel-tühjakslaadimisel; optimeerida sobivaid mikroaku arhitektuure.
Meetodid makrotasandis, mida selliste uuringute läbiviimiseks kasutatakse on lõplike elementide meetod (LEM) ning mikrotasandil molekulaardünaamilise simulatsiooni meetod (MD). Simulatsioonide läbiviimiseks kasutatakse LEM-i puhul tarkvarapakette COMSOL Multiphysics ja Elmer ning MD puhul tarkvarapaketti dl_poly.

= '''Aktuaatorid, seadmed ja nende juhtimine''' =
==IPMC elektromehhaanilisi omadusi uuriva seadme juhtimine==

Töö eesmärgiks on koostada eksperimentaalne seade, mis mõõdab elektroaktiivsete polümeeride elektromehaanilisi omadusi. Materjale kasutatakse kunstlihastena erinevates rakendustes. Töö tulemuseks peab valmima moodul, mis võimaldab seadet juhtuda USB kaudu.

==IPMC täitureid kasutava autonoomse seadme konstrueerimine==

Eesmärgiks on nn kunstlihaeid kasutavate materjalide abil liikuvate autonoomsete seadmete konstrueerimine ning töö kirjeldamine. Valik ideid: "putukas", ratas, minipurilennuk, mikrohumanoid jne.

==Süsinik-polümeermaterjalidest täiturite juhtimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi. St. vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomine, nende mudelite kirjeldamine ning eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureus, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

==IPMC/süsinik polümeermaterjalidest energiakogujate uurimine==

Töö eesmärgiks on parametriseerida ning uurida materjaliteadlaste poolt laboris loodud uudsete materjalide elektromehaanilisi omadusi eesmärgiga vinkeskkonnas olevate vibratsioonidest saadav energia muundada elektrienergiaks. Töö kujutab endast vajalike elektromehaaniliste ja füüsikaliskeemiliste mudelite loomist, nende mudelite kirjeldamine nin eksperimentaalsete tulemuste vastu kinnitamine. Töö sobib (erinevates mahtudes) bakalaureuse, magistri ja doktoritöödeks. Vajalik on võõrkeele oskus ning soov ja võimalus töötada aegajalt erinevates laborites välismaa ülikoolides.

== Lahedad ideed kunstlihaste rakendamiseks==
=== Ilmekas uksekoputi ===

Teha kunstlihastest ilmekas uksekoputi, vt. http://www.youtube.com/watch?feature=player_detailpage&v=-Kee7iyp_3U&list=TLC5Famb33RxE

= '''Signal and Image Processing''' ''(Signaali ja Pilditöötluse)'' =

''If you are interested in doing any of the following projects as your BSc project or if you would like to get more information please feel free to contact me via shb-AT-ut-DOT-ee''

For full list of project description please visit http://icv.ims.ut.ee/projectspage.html [[http://icv.ims.ut.ee/projectspage.html]]

= '''Robotic''' =

For more projects please visit http://icv.ims.ut.ee/projectspage.html

= '''Partneritega seotud teemad''' =

==Mehhanoelektriliste andurite uurimine==

Töö eesmärgiks on eksperimentaalselt uurida erinevate mehaanilist liigutust elektriliseks muundavate materjalide omadusi. Töö hõlmab eksperimendi konstrueerimist ja arvutijuhitavate mõõtmiste teostamist LabVIEW keskkonnas. Sobib hästi arvutitehnika, füüsika ja materjaliteaduse tudengitele.

==Robotmannekeen rõivatööstusele==

Projekti eesmärgiks on arendada välja inimkeha kujuline mannekeeni alakeha rõivatööstusele kiirendamaks ning parendamaks disainerrõivaste väljatöötamist.
Projektis on vaja konstrueerida mehaanika sõlmed, realiseerida elektroonika juhtsõlmed, modeleerida ning luua algoritmid mannekeeni välispinna juhtimiseks ning arendada välja süsteemi kontroll tarkvara. Samuti on vaja arendada välja kasutajatarkvara. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

Projektil on ka konkreetne rakendus vt [http://www.fits.me www.fits.me]

==Puutetundlik sensor robotmannekeenile ==

Projekti eesmärgiks on arendada inimkeha kujuline mannekeenile puutetundlike "naha" välja arendamine.
Projektis on vaja uurida ja testida erinevaid sensoreid, Leida olulised mõõtevahemikud ja mõõtetäpsused vastavalt vajadusele rakenduses. Projekti käigus tuleb koostööd teha mitmete põnevate inimestega, kes on aktiivsed moe- ja rõivatööstuse vallas.
Sobib mitmeteks bakalaureuse ja magistritöödeks, sõltuvalt tasemest on ka töö maht erinev.

= '''Õppetööga seotud''' =
==Sensori-anduri töö uurimine ja juhendmaterjali koostamine==

Töö eesmärgiks on eksperimentaalselt parametriseerida robootikas/automaatikas kasutatav sensor/täitur ning tulemuse põhjal koostada protokoll ja metoodika selle kasutamiseks.

== Juhendmaterjali koostamine koolirobootika tarbeks==

Töö eesmärgiks on koostada õpetajatele juhendmaterjale ja põnevaid tööülesandeid, aga samuti ülesandeid, mis aitavad lastel õppida füüsikat, matemaatikat, keemiat ja bioloogiat.
-->

=Üldine info bakalaureuse- ja magistritöö tegijatele=

Teil on kaks juhendajat. Eeldame, et te vähemalt kord nädalas võtate vähemalt ühe juhendajaga kontakti ja arutate läbi oma mured ja tegemised. Lisaks ootame tudengitelt aktiivset osavõttu kord nädalas toimuvast labori seminarist ja journal club'ist, kus harjutatakse avalikku esinemist, et kaitsmisel oleks lihtsam.

Töö esimene versioon peab olema esitatud hiljemalt 1. maiks. Hilinemiseks sobivad ainult dokumentaalselt tõestatavad meditsiinilised põhjused. Esimene version peab sisaldama:
# sissejuhatust, mis räägib, miks projekti tulemus on vajalik ja mida teised selles valdkonnas maailmas teinud on;
# projekti teoreetilisi/matemaatilisi/mudeli aluseid lahti kirjutatuna;
# tehtud tegevuse detailset kirjeldust (detaile pole kunagi liiga palju, delete on lihtsaim funktsioon, mida juhendaja teie kirjaliku töö ümber kirjutamisel :) teha saab);
# töö tulemusi, st kas mõõtmistulemusi või seadme töötava! prototüübi tehniline kirjeldust ja seadet ennast;
# hinnangut oma tööle, st töö tulemuste edasise arengu analüüsi, tulemuste analüüsi ja hinnangut töö tulemuse kvaliteedile.