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Multiscale simulations and mechanics...

Li, Shaofan.

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Multiscale simulations and mechanics of biological materials

Record Type:	Electronic resources : Monograph/item
Title/Author:	Multiscale simulations and mechanics of biological materials/ edited by Shaofan Li, Dong Qian.
other author:	Li, Shaofan.
Published:	New York :Wiley, : 2013.,
Description:	1 online resource (475 p.)
[NT 15003449]:	About the Editors; List of Contributors; Preface; Part I MULTISCALE SIMULATION THEORY; 1 Atomistic-to-Continuum Coupling Methods for Heat Transfer in Solids; 1.1 Introduction; 1.2 The Coupled Temperature Field; 1.2.1 Spatial Reduction; 1.2.2 Time Averaging; 1.3 Coupling the MD and Continuum Energy; 1.3.1 The Coupled System; 1.3.2 Continuum Heat Transfer; 1.3.3 Augmented MD; 1.4 Examples; 1.4.1 One-Dimensional Heat Conduction; 1.4.2 Thermal Response of a Composite System; 1.5 Coupled Phonon-Electron Heat Transport; 1.6 Examples: Phonon-Electron Coupling.
[NT 15003449]:	1.6.1 Equilibration of Electron/Phonon Energies1.6.2 Laser Heating of a Carbon Nanotube; 1.7 Discussion; Acknowledgments; References; 2 Accurate Boundary Treatments for Concurrent Multiscale Simulations; 2.1 Introduction; 2.2 Time History Kernel Treatment; 2.2.1 Harmonic Chain; 2.2.2 Square Lattice; 2.3 Velocity Interfacial Conditions: Matching the Differential Operator; 2.4 MBCs: Matching the Dispersion Relation; 2.4.1 Harmonic Chain; 2.4.2 FCC Lattice; 2.5 Accurate Boundary Conditions: Matching the Time History Kernel Function; 2.6 Two-Way Boundary Conditions; 2.7 Conclusions.
[NT 15003449]:	AcknowledgmentsReferences; 3 A Multiscale Crystal Defect Dynamics and Its Applications; 3.1 Introduction; 3.2 Multiscale Crystal Defect Dynamics; 3.3 How and Why the MCDD Model Works; 3.4 Multiscale Finite Element Discretization; 3.5 Numerical Examples; 3.6 Discussion; Acknowledgments; Appendix; References; 4 Application of Many-Realization Molecular Dynamics Method to Understand the Physics of Nonequilibrium Processes in Solids; 4.1 Chapter Overview and Background; 4.2 Many-Realization Method; 4.3 Application of the Many-Realization Method to Shock Analysis; 4.4 Conclusions; Acknowledgments.
[NT 15003449]:	5.5.1 Verification of Bulk Electrostatic Stress5.5.2 Verification of Surface Electrostatic Stress; 5.6 Conclusions and Future Research; Acknowledgments; References; 6 Towards a General Purpose Design System for Composites; 6.1 Motivation; 6.2 General Purpose Multiscale Formulation; 6.2.1 The Basic Reduced-Order Model; 6.2.2 Enhanced Reduced-Order Model; 6.3 Mechanistic Modeling of Fatigue via Multiple Temporal Scales; 6.4 Coupling of Mechanical and Environmental Degradation Processes; 6.4.1 Mathematical Model; 6.4.2 Mathematical Upscaling; 6.4.3 Computational Upscaling; 6.5 Uncertainty Quantification of Nonlinear Model of Micro-Interfaces and Micro-Phases.
Subject:	Biomedical materials - Computer simulation. -
Online resource:	http://onlinelibrary.wiley.com/book/10.1002/9781118402955
ISBN:	9781118402955 (electronic bk.)

Multiscale simulations and mechanics of biological materials
Multiscale simulations and mechanics of biological materials[electronic resource] /edited by Shaofan Li, Dong Qian. - New York :Wiley,2013. - 1 online resource (475 p.)

References5 Multiscale, Multiphysics Modeling of Electromechanical Coupling in Surface-Dominated Nanostructures; 5.1 Introduction; 5.2 Atomistic Electromechanical Potential Energy; 5.2.1 Atomistic Electrostatic Potential Energy: Gaussian Dipole Method; 5.2.2 Finite Element Equilibrium Equations from Total Electromechanical Potential Energy; 5.3 Bulk Electrostatic Piola-Kirchoff Stress; 5.3.1 Cauchy-Born Kinematics; 5.3.2 Comparison of Bulk Electrostatic Stress with Molecular Dynamics Electrostatic Force; 5.4 Surface Electrostatic Stress; 5.5 One-Dimensional Numerical Examples.

About the Editors; List of Contributors; Preface; Part I MULTISCALE SIMULATION THEORY; 1 Atomistic-to-Continuum Coupling Methods for Heat Transfer in Solids; 1.1 Introduction; 1.2 The Coupled Temperature Field; 1.2.1 Spatial Reduction; 1.2.2 Time Averaging; 1.3 Coupling the MD and Continuum Energy; 1.3.1 The Coupled System; 1.3.2 Continuum Heat Transfer; 1.3.3 Augmented MD; 1.4 Examples; 1.4.1 One-Dimensional Heat Conduction; 1.4.2 Thermal Response of a Composite System; 1.5 Coupled Phonon-Electron Heat Transport; 1.6 Examples: Phonon-Electron Coupling.

Multiscale Simulations and Mechanics of Biological Materials A compilation of recent developments in multiscale simulation and computational biomaterials written by leading specialists in the field Presenting the latest developments in multiscale mechanics and multiscale simulations, and offering a unique viewpoint on multiscale modelling of biological materials, this book outlines the latest developments in computational biological materials from atomistic and molecular scale simulation on DNA, proteins, and nano-particles, to meoscale soft matter modelling.

ISBN: 9781118402955 (electronic bk.)Subjects--Topical Terms:

2084950
Biomedical materials
--Computer simulation.Index Terms--Genre/Form:

542853
Electronic books.

LC Class. No.: R857.M3 / M85 2013

Dewey Class. No.: 660.6

Multiscale simulations and mechanics of biological materials
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008 150109s2013 nyu ob 001 0 eng d
020 $a 9781118402955 (electronic bk.)
020 $a 1118402952 (electronic bk.)
020 $z 9781118452530
020 $z 1118452534
020 $z 9781118350799
035 $a (OCoLC)830163872
035 $a ocn830163872
040 $a EBLCP $b eng $e pn $c EBLCP $d OCLCQ $d DG1 $d IDEBK $d CDX $d OCLCQ
050 4 $a R857.M3 $b M85 2013
082 0 4 $a 660.6
245 0 0 $a Multiscale simulations and mechanics of biological materials $h [electronic resource] / $c edited by Shaofan Li, Dong Qian.
260 $a New York : $b Wiley, $c 2013.
300 $a 1 online resource (475 p.)
504 $a References5 Multiscale, Multiphysics Modeling of Electromechanical Coupling in Surface-Dominated Nanostructures; 5.1 Introduction; 5.2 Atomistic Electromechanical Potential Energy; 5.2.1 Atomistic Electrostatic Potential Energy: Gaussian Dipole Method; 5.2.2 Finite Element Equilibrium Equations from Total Electromechanical Potential Energy; 5.3 Bulk Electrostatic Piola-Kirchoff Stress; 5.3.1 Cauchy-Born Kinematics; 5.3.2 Comparison of Bulk Electrostatic Stress with Molecular Dynamics Electrostatic Force; 5.4 Surface Electrostatic Stress; 5.5 One-Dimensional Numerical Examples.
504 $a Includes bibliographical references and index.
505 0 $a About the Editors; List of Contributors; Preface; Part I MULTISCALE SIMULATION THEORY; 1 Atomistic-to-Continuum Coupling Methods for Heat Transfer in Solids; 1.1 Introduction; 1.2 The Coupled Temperature Field; 1.2.1 Spatial Reduction; 1.2.2 Time Averaging; 1.3 Coupling the MD and Continuum Energy; 1.3.1 The Coupled System; 1.3.2 Continuum Heat Transfer; 1.3.3 Augmented MD; 1.4 Examples; 1.4.1 One-Dimensional Heat Conduction; 1.4.2 Thermal Response of a Composite System; 1.5 Coupled Phonon-Electron Heat Transport; 1.6 Examples: Phonon-Electron Coupling.
505 8 $a 1.6.1 Equilibration of Electron/Phonon Energies1.6.2 Laser Heating of a Carbon Nanotube; 1.7 Discussion; Acknowledgments; References; 2 Accurate Boundary Treatments for Concurrent Multiscale Simulations; 2.1 Introduction; 2.2 Time History Kernel Treatment; 2.2.1 Harmonic Chain; 2.2.2 Square Lattice; 2.3 Velocity Interfacial Conditions: Matching the Differential Operator; 2.4 MBCs: Matching the Dispersion Relation; 2.4.1 Harmonic Chain; 2.4.2 FCC Lattice; 2.5 Accurate Boundary Conditions: Matching the Time History Kernel Function; 2.6 Two-Way Boundary Conditions; 2.7 Conclusions.
505 8 $a AcknowledgmentsReferences; 3 A Multiscale Crystal Defect Dynamics and Its Applications; 3.1 Introduction; 3.2 Multiscale Crystal Defect Dynamics; 3.3 How and Why the MCDD Model Works; 3.4 Multiscale Finite Element Discretization; 3.5 Numerical Examples; 3.6 Discussion; Acknowledgments; Appendix; References; 4 Application of Many-Realization Molecular Dynamics Method to Understand the Physics of Nonequilibrium Processes in Solids; 4.1 Chapter Overview and Background; 4.2 Many-Realization Method; 4.3 Application of the Many-Realization Method to Shock Analysis; 4.4 Conclusions; Acknowledgments.
505 8 $a 5.5.1 Verification of Bulk Electrostatic Stress5.5.2 Verification of Surface Electrostatic Stress; 5.6 Conclusions and Future Research; Acknowledgments; References; 6 Towards a General Purpose Design System for Composites; 6.1 Motivation; 6.2 General Purpose Multiscale Formulation; 6.2.1 The Basic Reduced-Order Model; 6.2.2 Enhanced Reduced-Order Model; 6.3 Mechanistic Modeling of Fatigue via Multiple Temporal Scales; 6.4 Coupling of Mechanical and Environmental Degradation Processes; 6.4.1 Mathematical Model; 6.4.2 Mathematical Upscaling; 6.4.3 Computational Upscaling; 6.5 Uncertainty Quantification of Nonlinear Model of Micro-Interfaces and Micro-Phases.
520 $a Multiscale Simulations and Mechanics of Biological Materials A compilation of recent developments in multiscale simulation and computational biomaterials written by leading specialists in the field Presenting the latest developments in multiscale mechanics and multiscale simulations, and offering a unique viewpoint on multiscale modelling of biological materials, this book outlines the latest developments in computational biological materials from atomistic and molecular scale simulation on DNA, proteins, and nano-particles, to meoscale soft matter modelling.
588 0 $a Print version record.
650 0 $a Biomedical materials $x Computer simulation. $3 2084950
650 0 $a Biomedical materials $x Mechanical properties. $3 2084951
655 4 $a Electronic books. $2 lcsh $3 542853
700 1 $a Li, Shaofan. $3 1005080
700 1 $a Qian, Dong. $3 2084949
856 4 0 $u http://onlinelibrary.wiley.com/book/10.1002/9781118402955