A Thermodynamical Theory of Plastic Spin and Internal Stress With Dislocation Density Tensor

K. Shizawa; H. M. Zbib

Source: Journal of Engineering Materials and Technology:;1999:;volume( 121 ):;issue: 002::page 247

Author:

K. Shizawa

H. M. Zbib

DOI: 10.1115/1.2812372

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A thermodynamical theory of elastoplasticity including kinematic hardening and dislocation density tensor is developed. The theory is self-consistent and is based on two fundamental principles of thermodynamics, i.e., the principle of increase of entropy and maximal entropy production rate. The thermodynamically consistent governing equations of plastic spin and back stress are rigorously derived. An expression for the plastic spin tensor is obtained from the constitutive equation of dislocation drift rate tensor and an expression for the back stress tensor is given as a balance equation expressing an equilibrium between internal stress and microstress conjugate to the dislocation density tensor. Moreover, it is shown that, in order to obtain a thermodynamically consistent theory for kinematic hardening, the free energy density should have the dislocation density tensor as one of its arguments.

keyword(s): Stress , Particle spin , Tensors , Dislocation density , Equations , Entropy , Hardening , Equilibrium (Physics) , Dislocations , Elastoplasticity , Stress tensors , Density AND Thermodynamics ,

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A Thermodynamical Theory of Plastic Spin and Internal Stress With Dislocation Density Tensor

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contributor author	K. Shizawa
contributor author	H. M. Zbib
date accessioned	2017-05-08T23:59:51Z
date available	2017-05-08T23:59:51Z
date copyright	April, 1999
date issued	1999
identifier issn	0094-4289
identifier other	JEMTA8-26997#247_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/122258
description abstract	A thermodynamical theory of elastoplasticity including kinematic hardening and dislocation density tensor is developed. The theory is self-consistent and is based on two fundamental principles of thermodynamics, i.e., the principle of increase of entropy and maximal entropy production rate. The thermodynamically consistent governing equations of plastic spin and back stress are rigorously derived. An expression for the plastic spin tensor is obtained from the constitutive equation of dislocation drift rate tensor and an expression for the back stress tensor is given as a balance equation expressing an equilibrium between internal stress and microstress conjugate to the dislocation density tensor. Moreover, it is shown that, in order to obtain a thermodynamically consistent theory for kinematic hardening, the free energy density should have the dislocation density tensor as one of its arguments.
publisher	The American Society of Mechanical Engineers (ASME)
title	A Thermodynamical Theory of Plastic Spin and Internal Stress With Dislocation Density Tensor
type	Journal Paper
journal volume	121
journal issue	2
journal title	Journal of Engineering Materials and Technology
identifier doi	10.1115/1.2812372
journal fristpage	247
journal lastpage	253
identifier eissn	1528-8889
keywords	Stress
keywords	Particle spin
keywords	Tensors
keywords	Dislocation density
keywords	Equations
keywords	Entropy
keywords	Hardening
keywords	Equilibrium (Physics)
keywords	Dislocations
keywords	Elastoplasticity
keywords	Stress tensors
keywords	Density AND Thermodynamics
tree	Journal of Engineering Materials and Technology:;1999:;volume( 121 ):;issue: 002
contenttype	Fulltext

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