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A review of computational methods in materials science: examples from shock-wave and polymer physics

This review discusses several computational methods used on different length and time scales for the simulation of material behavior. First, the importance of physical modeling and its relation to computer simulation on multiscales is discussed. Then, computational methods used on different scales a...

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Published in:	International journal of molecular sciences 2009-12, Vol.10 (12), p.5135-5216
Main Authors:	Steinhauser, Martin O, Hiermaier, Stefan
Format:	Article
Language:	English
Subjects:	Biopolymers - chemistry Dendrimers - chemistry Materials science Materials Testing Molecular Dynamics Simulation Review
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creator	Steinhauser, Martin O Hiermaier, Stefan
description	This review discusses several computational methods used on different length and time scales for the simulation of material behavior. First, the importance of physical modeling and its relation to computer simulation on multiscales is discussed. Then, computational methods used on different scales are shortly reviewed, before we focus on the molecular dynamics (MD) method. Here we survey in a tutorial-like fashion some key issues including several MD optimization techniques. Thereafter, computational examples for the capabilities of numerical simulations in materials research are discussed. We focus on recent results of shock wave simulations of a solid which are based on two different modeling approaches and we discuss their respective assets and drawbacks with a view to their application on multiscales. Then, the prospects of computer simulations on the molecular length scale using coarse-grained MD methods are covered by means of examples pertaining to complex topological polymer structures including star-polymers, biomacromolecules such as polyelectrolytes and polymers with intrinsic stiffness. This review ends by highlighting new emerging interdisciplinary applications of computational methods in the field of medical engineering where the application of concepts of polymer physics and of shock waves to biological systems holds a lot of promise for improving medical applications such as extracorporeal shock wave lithotripsy or tumor treatment.
doi_str_mv	10.3390/ijms10125135
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subjects	Biopolymers - chemistry Dendrimers - chemistry Materials science Materials Testing Molecular Dynamics Simulation Review
title	A review of computational methods in materials science: examples from shock-wave and polymer physics
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