Polymers: Dendrimers-network-electrolye-nlo

William A. Goddard

doi:10.1007/978-3-030-18778-1_67

Polymers: Dendrimers-network-electrolye-nlo

William A. Goddard

California Institute of Technology

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Our group has been a leader in building realistic models of polymers using force fields based upon quantum chemical calculations. We have carried out large-scale molecular dynamics simulations of these systems to elucidate fundamental materials properties, using the molecular simulation technology described above. Highlights are the first simulations of the Tomalia dendrimers, the Percec dendritic system and the Frechet systems. We also carried out the first simulations on polyethylene and nylon. Later we carried out the first realistic simulations on the Nafion electrolyte for fuel cells. More recent work is on PEO polymer electrolytes for Li batteries. Along the way, we developed efficient methodologies to predict the structures of amorphous polymers using thermal and volume quenching and finally scaled effective solvent (SES) methodology. We extended these ideas to network polymers and nonlinear optical materials.

Original language	English
Title of host publication	Springer Series in Materials Science
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	1283-1295
Number of pages	13
DOIs	https://doi.org/10.1007/978-3-030-18778-1_67
Publication status	Published - 1 Jan 2021
Externally published	Yes

Publication series

Name	Springer Series in Materials Science
Volume	284
ISSN (Print)	0933-033X
ISSN (Electronic)	2196-2812

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10.1007/978-3-030-18778-1_67

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abstract = "Our group has been a leader in building realistic models of polymers using force fields based upon quantum chemical calculations. We have carried out large-scale molecular dynamics simulations of these systems to elucidate fundamental materials properties, using the molecular simulation technology described above. Highlights are the first simulations of the Tomalia dendrimers, the Percec dendritic system and the Frechet systems. We also carried out the first simulations on polyethylene and nylon. Later we carried out the first realistic simulations on the Nafion electrolyte for fuel cells. More recent work is on PEO polymer electrolytes for Li batteries. Along the way, we developed efficient methodologies to predict the structures of amorphous polymers using thermal and volume quenching and finally scaled effective solvent (SES) methodology. We extended these ideas to network polymers and nonlinear optical materials.",

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AB - Our group has been a leader in building realistic models of polymers using force fields based upon quantum chemical calculations. We have carried out large-scale molecular dynamics simulations of these systems to elucidate fundamental materials properties, using the molecular simulation technology described above. Highlights are the first simulations of the Tomalia dendrimers, the Percec dendritic system and the Frechet systems. We also carried out the first simulations on polyethylene and nylon. Later we carried out the first realistic simulations on the Nafion electrolyte for fuel cells. More recent work is on PEO polymer electrolytes for Li batteries. Along the way, we developed efficient methodologies to predict the structures of amorphous polymers using thermal and volume quenching and finally scaled effective solvent (SES) methodology. We extended these ideas to network polymers and nonlinear optical materials.

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M3 - Chapter

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SP - 1283

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BT - Springer Series in Materials Science

PB - Springer Science and Business Media Deutschland GmbH

ER -

Polymers: Dendrimers-network-electrolye-nlo

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