Computer-Aided Materials Design for Proton-Conducting Fluoropolymers - Revision history

Alvo at 04:47, 25 August 2007

2007-08-25T04:47:02Z

@@ Line 24: / Line 24: @@
 * the effects of Nafion side chains on the proton dynamics.
-==Contact==
+==People==
 [[User:Alvo|Alvo Aabloo]]

Alvo at 15:00, 9 February 2007

2007-02-09T15:00:27Z

← Older revision		Revision as of 18:00, 9 February 2007
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	* simulations of proton hopping mechanism between Nafion chain and surrounding water,		* simulations of proton hopping mechanism between Nafion chain and surrounding water,
	* the effects of Nafion side chains on the proton dynamics.		* the effects of Nafion side chains on the proton dynamics.

			==Contact==
			[[User:Alvo\|Alvo Aabloo]]

Alvo at 14:34, 9 February 2007

2007-02-09T14:34:08Z

← Older revision		Revision as of 17:34, 9 February 2007
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			===Computer-Aided Materials Design===
	==Computer-Aided Materials Design==

	Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.		Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.
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	Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.		Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.

	==Proton-conducting fluoropolymers==		===Proton-conducting fluoropolymers===

	A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.		A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.
Line 18:		Line 17:
	Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.		Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.

	==The Aim of the Project==		===The Aim of the Project===
	Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.		Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.
	We are interested in following research problems:		We are interested in following research problems:

Alvo at 14:32, 9 February 2007

2007-02-09T14:32:03Z

← Older revision		Revision as of 17:32, 9 February 2007
Line 1:		Line 1:

	==Computer-Aided Materials Design==		==Computer-Aided Materials Design==

	Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.		Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.
			But not only new materials - computer-aided materials design involves also the analysis and exploring of the properties of already existing materials. In computer calculations, it is often common that complexity of the system must be reduced or simpler subsystems created. These must be simpler enough to by viable models, so that analytical and/or numerical methods can be used to analyse the system and its properties.
			Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.

	~~But not only new materials~~ - computer-aided materials design involves also the analysis and exploring of the properties of already existing materials. In computer calculations, it is often common that complexity of the system must be reduced or simpler subsystems created. These must be simpler enough to by viable models, so that analytical and/or numerical methods can be used to analyse the system and its properties.		==Proton-conducting fluoropolymers==

	Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.
	~~===Proton-conducting fluoropolymers===~~
	A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.		A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.

Line 17:		Line 18:
	Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.		Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.

	===The ~~Aims~~ of the Project===		==The Aim of the Project==
	Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.		Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.
	We are interested in following research problems:		We are interested in following research problems:

Alvo at 14:30, 9 February 2007

2007-02-09T14:30:35Z

← Older revision		Revision as of 17:30, 9 February 2007
Line 1:		Line 1:
	===Computer-Aided Materials Design===		==Computer-Aided Materials Design==

	Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.		Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.

Alvo: /* Proton-conducting fluoropolymers */

2007-02-09T14:28:39Z

Proton-conducting fluoropolymers

← Older revision		Revision as of 17:28, 9 February 2007
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	Nafion® is DuPont's trademark of a sulfonated tetrafluoroethylene polymer modified from Teflon®. It is the first member of synthetic polymers with ionic properties which are latter called ionomers. Nafion's ionic properties were created by introducing sulfonic acid groups into the bulk polymer matrix of Teflon. Nafion® is usually used to make ion-exchange membrane for applications such as Proton Exchange (or Polymer Electrolyte) Membrane Fuel Cells. Its ability to conduct hydrogen ions (protons) but not water or electrons are what qualifies if for this task.		Nafion® is DuPont's trademark of a sulfonated tetrafluoroethylene polymer modified from Teflon®. It is the first member of synthetic polymers with ionic properties which are latter called ionomers. Nafion's ionic properties were created by introducing sulfonic acid groups into the bulk polymer matrix of Teflon. Nafion® is usually used to make ion-exchange membrane for applications such as Proton Exchange (or Polymer Electrolyte) Membrane Fuel Cells. Its ability to conduct hydrogen ions (protons) but not water or electrons are what qualifies if for this task.

	[[Image:Nafion1.png]]		[[Image:Nafion1.png]]

Line 15:		Line 16:

	Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.		Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.

	===The Aims of the Project===		===The Aims of the Project===
	Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.		Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.

Alvo at 14:28, 9 February 2007

2007-02-09T14:28:25Z

← Older revision		Revision as of 17:28, 9 February 2007
Line 7:		Line 7:
	Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.		Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.
	===Proton-conducting fluoropolymers===		===Proton-conducting fluoropolymers===

	A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.		A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.

	Nafion® is DuPont's trademark of a sulfonated tetrafluoroethylene polymer modified from Teflon®. It is the first member of synthetic polymers with ionic properties which are latter called ionomers. Nafion's ionic properties were created by introducing sulfonic acid groups into the bulk polymer matrix of Teflon. Nafion® is usually used to make ion-exchange membrane for applications such as Proton Exchange (or Polymer Electrolyte) Membrane Fuel Cells. Its ability to conduct hydrogen ions (protons) but not water or electrons are what qualifies if for this task.		Nafion® is DuPont's trademark of a sulfonated tetrafluoroethylene polymer modified from Teflon®. It is the first member of synthetic polymers with ionic properties which are latter called ionomers. Nafion's ionic properties were created by introducing sulfonic acid groups into the bulk polymer matrix of Teflon. Nafion® is usually used to make ion-exchange membrane for applications such as Proton Exchange (or Polymer Electrolyte) Membrane Fuel Cells. Its ability to conduct hydrogen ions (protons) but not water or electrons are what qualifies if for this task.
			[[Image:Nafion1.png]]

	Figure: a segment of the Nafion® chain		Figure: a segment of the Nafion® chain

	Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.		Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.
	The Aims of the Project		===The Aims of the Project===

	Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.		Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.
	We are interested in following research problems:		We are interested in following research problems:
			* design of the realistic and reliable Molecular Dynamics simulation model for Nafion as an electrolyte in the fuel cell,
	* design of the realistic and reliable Molecular Dynamics simulation model for Nafion as an electrolyte in the fuel cell,		* simulations of proton hopping mechanism between Nafion chain and surrounding water,
	* simulations of proton hopping mechanism between Nafion chain and surrounding water,		* the effects of Nafion side chains on the proton dynamics.
	* the effects of Nafion side chains on the proton dynamics.

Alvo at 14:26, 9 February 2007

2007-02-09T14:26:50Z

New page

===Computer-Aided Materials Design===

Producing useful new materials would be easier if we could calculate their properties before actually making them. A complete description from first principles is impossibly complex, but computer-aided materials design is enabling progress in linking the electronic, atomistic, microstructural and continuum levels.

But not only new materials - computer-aided materials design involves also the analysis and exploring of the properties of already existing materials. In computer calculations, it is often common that complexity of the system must be reduced or simpler subsystems created. These must be simpler enough to by viable models, so that analytical and/or numerical methods can be used to analyse the system and its properties.

Care must be taken to ensure that the models are as realistic as possible and that their properties prior to the simulations have physical and chemical meaning. For example, the predictions of the computer simulations can only be as reliable as the interatomic potentials used since the gradient of the potential determines the interatomic forces that enter Newton's laws of motion. An unphysical interatomic potential used as a input will lead to unphysical behaviour as output in accordance with GIGO principle of computing, namely Garbage In Garbage Out.
===Proton-conducting fluoropolymers===

A fluoropolymer is a polymer that contains atoms of fluorine. They were characterised by an unusual resistance to solvents, acids, and bases. Fluoropolymers were discovered serendipitously in 1938 by Dr. Roy J. Plunkett. He was working on freon and accidentally polymerised tetrafluoroethylene. The result was polytertafluoroethylene (PTFE) - Teflon®. It turned out to be the most slippery material known to the man and inert to virtually all chemicals.

Nafion® is DuPont's trademark of a sulfonated tetrafluoroethylene polymer modified from Teflon®. It is the first member of synthetic polymers with ionic properties which are latter called ionomers. Nafion's ionic properties were created by introducing sulfonic acid groups into the bulk polymer matrix of Teflon. Nafion® is usually used to make ion-exchange membrane for applications such as Proton Exchange (or Polymer Electrolyte) Membrane Fuel Cells. Its ability to conduct hydrogen ions (protons) but not water or electrons are what qualifies if for this task.

Figure: a segment of the Nafion® chain

Nafion belongs to the wide class of solid superacids catalysts, in that it exhibits acid strength greater than that of 100% H2SO4. It has hydrophobic (-CF2-CF2-) and hydrophilic (-SO3H) regions in its polymeric structure, and its supeacidity is attributed to the electron-withdrawing effect of the perfluorocarbon chain acting on the sulfonic acid group. Nafion is able to catalyze various reactions, such as alkylation, disproportionation, and esterification.
The Aims of the Project

Molecular Dynamics (MD) simulations give us a chance to have close insights into Nafion's dynamics and local structure on molecular level. We can study the details of proton-conductivity and find out the mechanisms what can possibly improve this process.
We are interested in following research problems:

* design of the realistic and reliable Molecular Dynamics simulation model for Nafion as an electrolyte in the fuel cell,
* simulations of proton hopping mechanism between Nafion chain and surrounding water,
* the effects of Nafion side chains on the proton dynamics.