基于位錯(cuò)機(jī)制的微米：亞微米尺度晶體塑性理論和計(jì)算（英文版）

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作　者：	莊茁，柳占立，崔一南
出版社：	清華大學(xué)出版社
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ISBN：	9787302546368	出版時(shí)間：	2020-08-01	包裝：
開(kāi)本：	16開(kāi)	頁(yè)數(shù)：	452	字?jǐn)?shù)：

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　　《基于位錯(cuò)機(jī)制的微米-亞微米尺度晶體塑性理論和計(jì)算（英文版）》展示了在微米和亞微米尺度基于位錯(cuò)機(jī)制的晶體塑性理論模型和計(jì)算方法，便于理解“越細(xì)越硬”的強(qiáng)度尺寸效應(yīng)。相比普遍認(rèn)知的預(yù)應(yīng)變引起硬化和退火引起軟化，在小尺度材料上展示了相反的結(jié)果，即預(yù)應(yīng)變引起軟化和退火引起硬化。在晶體中觀測(cè)到的反常規(guī)本構(gòu)關(guān)系，例如，屈服強(qiáng)度的尺度依賴(lài)性，微柱壓縮過(guò)程中的間隙塑性流動(dòng)。這些新的反常規(guī)的力學(xué)特點(diǎn)改變了人們對(duì)連續(xù)介質(zhì)力學(xué)和塑性流動(dòng)行為的傳統(tǒng)認(rèn)識(shí)。

作者簡(jiǎn)介

　　莊茁，清華大學(xué)航天航空學(xué)院教授，先進(jìn)力學(xué)與材料中心主任，國(guó)防973項(xiàng)目首席科學(xué)家。在動(dòng)態(tài)斷裂力學(xué)、非線性有限元和亞微米尺度晶體塑性的理論和計(jì)算等方面做出國(guó)際l先的科學(xué)成果；在飛機(jī)穿蓋彈射救生系統(tǒng)、西氣東輸管線韌性止裂和頁(yè)巖水力壓裂體積改造等國(guó)家重大工程中做出重要的技術(shù)成果。發(fā)表學(xué)術(shù)論文280余篇，含SCI期刊130余篇；出版18部書(shū)。獲得國(guó)j級(jí)和省部級(jí)的科技和教育成果獎(jiǎng)勵(lì)10余項(xiàng)。中國(guó)力學(xué)學(xué)會(huì)常務(wù)理事、計(jì)算力學(xué)專(zhuān)業(yè)委員會(huì)主任委員。國(guó)際計(jì)算力學(xué)學(xué)會(huì)理事。教育部高等學(xué)校力學(xué)類(lèi)專(zhuān)業(yè)教學(xué)指導(dǎo)委員會(huì)副主任委員。

圖書(shū)目錄

Contents
Chapter 1: Background and Signi.cance ..................... 1
1.1 Framework of This Book............................................... 1
1.2 Polycrystalline and Single-Crystal Plasticity ......................... 3
1.3 Size Effect on Crystal Plasticity at Micron and Submicron Scales..............................................5
1.3.1 Size Effect Observed in Material Experiments ................................................ 5
1.3.2 Size Effect of Yield Stress ........................................... 7
1.3.3 Strain Burst and Dislocation Avalanches........................................................12
1.3.4 Size Effect of Submicron Crystal Under Cyclic Loading.............................. 14
1.3.5 Size Effect of Deformation Morphology of Compressed Micropillars .............................................. 16
1.4 Method to Bridge Size Effect............................................ 17
1.4.1 Supersurface From Macro to Micron..................................17
1.4.2 Nonlocal Crystal Plasticity .................................................... 19
1.4.3 Discrete Dislocation Dynamics Simulation Method............. 21
1.5 Content of This Book .................. 22
Part 1 Continuum Dislocation Mechanism-Based Crystal Plasticity ......27
Chapter 2: Fundamental Conventional Concept of Plasticity Constitution .............. 29
2.1 Introduction ............................................. 29
2.2 One-Dimensional Plasticity ............................................ 30
2.2.1 Isotropic Hardening.................................................... 30
2.2.2 Kinematic Hardening ............................ 33
2.2.3 Rate-Dependent Plasticity............................................... 35
2.3 Multiaxial Plasticity ....................................................... 37
2.3.1 Hypoelastic-Plastic Materials .................................... 37
2.3.2 Small Strain Plasticity .................................................. 41
2.4 J2 Flow Theory Plasticity ............................................... 42
2.4.1 Kirchhoff Stress Formulation of J2 Flow Theory Plasticity .......................... 42
2.4.2 Extension to Kinematic Hardening ............................ 44
2.4.3 Large Strain Viscoplasticity......................................... 46
Contents
2.5 Rock-Soil Constitutive Model .......................................... 47
2.5.1 Mohr-Coulomb Constitutive Model ...................... 47
2.5.2 Drucker-Prager Constitutive Model..................... 49
2.6 Gurson Model for Porous Elastic-Plastic Solids.............. 51
2.7 Corotational Stress Formulation ..................... 54
2.8 Summary ............................................ 56
Chapter 3: Strain Gradient Plasticity Theory at the Microscale............................ 57
3.1 Size Dependence of Material Behavior at the Microscale.................................57
3.2 Couple Stress Theory...............................................60
3.2.1 Couple Stresses ............................................ 60
3.2.2 Rotation and Rotation Gradient..................................... 62
3.2.3 Virtual Work Principle..................................................64
3.2.4 Constitutive Relation of Couple Stress Strain Gradient Plasticity Theory ................................... 65
3.2.5 Principles of Minimum Potential Energy and Minimum Complementary Energy .......................................... 66
3.2.6 Equivalent Stress and Equivalent Strain ................... 67
3.3 Stretch and Rotation Gradient Theory ................. 70
3.3.1 Strain Gradient Tensor............................71
3.3.2 Decomposition of Strain Gradient Partial Tensor h0 and Total Equivalent Strain ESG............................... 72
3.3.3 Constitutive Relation of Stretch and Rotation Gradient Strain Gradient Plastic Theory ........................... 76
3.4 Microscale Mechanism-Based Strain Gradient Plasticity Theory ......................................... 78
3.4.1 Experimental Law for Strain Gradient Plasticity Theory...................... 79
3.4.2 Motivation for Microscale Mechanism-Based Strain Gradient Plasticity Theory..................................81
3.4.3 Microscale Computation Framework ................... 82
3.4.4 Dislocation Model.......................................................84
3.4.5 Constitutive Equation of Mechanism-Based Strain Gradient Plasticity Theory...........................................84
3.4.6 Size of Cell Element at the Microscale .............. 86
3.4.7 Mechanism-Based Strain Gradient Plasticity Predicts Stress Singularity at Crack Tip ........................... 88
3.5 Summary ........................................ 89
Chapter 4: Dislocation-Based Single-Crystal Plasticity Model .................... 91
4.1 Introduction ...................................... 92
4.2 General Constitutive Model for Single Crystals.................92
4.2.1 Basic Kinematics of Crystal Plasticity............... 92
4.2.2 Slip Rate and Dislocation Density Evolution .................. 95
4.2.3 Plastic Stress Required for Dislocation Motion .............. 102
4.2.4 Update of Cauchy Stress in Single-Crystal Plasticity ........ 103
Contents
4.3 Higher-Order Dislocation Dynamics-Based Crystal Plasticity Model .................... 104
4.3.1 Governing Equations of Macroforces .................................... 104
4.3.2 Governing Equations of Microforces ................... 105
4.3.3 Coupling of Macroscopic and Microscopic Equations.......... 108
4.4 Size and Bauschinger Effect in Passivated Thin Films.........109
4.4.1 Two Hardening Mechanisms Caused by Geometrically Necessary Dislocations .......................................... 109
4.4.2 Model Description........................ 110
4.4.3 Size Effect of Passivated Thin Films Under Tension......... 112
4.4.4 Bauschinger Effect of Passivated Thin Films During Unloading ....................... 113
4.5 Summary ........................................ 118
Chapter 5: Revealing the Size Effect in Micropillars by Dislocation-Based Crystal Plasticity Theory ..................................... 121
5.1 Introduction ........................... 121
5.2 Strain Burst and Size Effect in Compression Micropillars .............................. 122
5.2.1 Stochastic Crystal Plasticity Model................... 122
5.2.2 Determination of Size-Dependent Slip Resistance....................124
5.2.3 Strain Bursts at Small Scales ......................................... 130
5.2.4 Application to the Compression of Single-Crystal Ni Micron Pillars ........................................................ 133
5.3 Size-Dependent Deformation Morphology of Micropillars.............................. 137
5.3.1 Simulation Setups ....................................................... 138
5.3.2 Size-Dependent Deformation Morphology ................................................... 140
5.3.3 Role of Short-Range Back Stress..................................... 143
5.3.4 Critical Transition Size ....................................................... 143
5.3.5 Discussions of Material Softening .................................. 147
5.4 Summary .................................... 149
Chapter 6: Microscale Crystal Plasticity Model Based on Phase Field Theory............................................... 151
6.1 Introduction ........................................... 151
6.2 Theoretical Model............................................153
6.2.1 Basic Equations of Crystal Plasticity Theory............................153
6.2.2 Phase Field Description of Plastic Slip....................................... 154
6.2.3 Stored Energy and Dissipated Energy ....................................... 155
6.2.4 Principle of Virtual Power..........................157
6.2.5 Coupled Balance Equations...........................158
6.2.6 Finite Element Discretization ............................. 159
6.3 Computational Demonstrations............................ 160
6.3.1 Dislocation Near a Free Surface ....................... 161
6.3.2 Dislocation in an Anisotropic Material...................162
6.3.3 Dislocation Near a Bimaterial Interface ............ 163
Contents
6.4 Applications to Heteroepitaxial Structures ................ 165
6.4.1 Critical Shell Thickness of Core-Shell Nanopillars ...... 166
6.4.2 Dislocations in Heteroepitaxial Thin Films ........... 169
6.5 Summary .............................................. 172
Part 2 Discrete Dislocation Mechanism-Based Crystal Plasticity ..........................................175 Chapter 7: Discrete-Continuous Model of Crystal Plasticity at the Submicron Scale ................................. 177
7.1 Discrete Dislocation Dynamics ............................................. 177
7.1.1 Dislocation Kinetic.............................. 179
7.1.2 Dislocation Interactions and Topology Update......................... 181
7.1.3 Dislocation Cross-Slip .................................... 182
7.1.4 Current Three-Dimensional Discrete Dislocation Dynamics Simulations .................................. 183
7.2 Coupling Discrete Dislocation Dynamics With Finite Element Method.............................................185
7.2.1 Superposition Method...................................185
7.2.2 Discrete-Continuous Model ......................... 187
7.3 Improved Discrete-Continuous Model .................... 189
7.3.1 Ef.cient Regularization Method .................. 189
7.3.2 Image Force Calculation.................... 198
7.3.3 Finite Deformation.................................203
7.4 Application to Heteroepitaxial Films ................................... 209
7.4.1 Thermoelastic Calculation to Determine Internal Stress Field........................................................209
7.4.2 In.uence of Substrate Thickness on Dislocation Behavior...................................... 210
7.5 Application to Irradiated Materials .................................. 213
7.6 Summary ......................................... 217
Chapter 8: Single-Arm Dislocation Source (SAS)-Controlled Submicron Plasticity ............................... 219
8.1 Introduction .................................. 219
8.2 Single-Arm Dislocation Source Mechanisms at Submicron Scales......................................221
8.3 Single-Arm Dislocation Source-Controlled Strain Burst and Dislocation Avalanche ................................. 222
8.4 Description of Single-Arm Dislocation Source-Controlled Plasticity ............. 226
8.4.1 Single-Arm Dislocation Source-Controlled Dislocation Density Evolution ...................................... 226
8.4.2 Effective Single-Arm Dislocation Source Length ............................... 230
8.4.3 Single-Arm Dislocation Source-Controlled Flow Stress ..................... 232
8.5 Summary ......................................... 237
Contents
Chapter 9: Con.ned Plasticity in Micropillars........................................ 239
9.1 Insights into Coated Micropillar Plasticity ...................................... 240
9.1.1 Stress-Strain Curves in Coated and Uncoated Pillars ......................... 240
9.1.2 Dislocation Source Mechanism in Coated Micropillars........................241
9.1.3 Back Stress in Coated Micropillars...................................... 244
9.1.4 Evolution of Mobile and Trapped Dislocation ............................... 245
9.2 Implications for Crystal Plasticity Model .................................... 247
9.3 Theoretical Models for Coated Micropillars........................... 252
9.3.1 Dislocation Density Evolution Model..............................253
9.3.2 Prediction of Stress-Strain Curve...................................255
9.4 Brief Discussion on Coating Failure Mechanism .......... 257
9.4.1 High Hoop Stress of Coated Layer......................................258
9.4.2 Transmission Effect of Dislocations Across Coating ......................... 258
9.5 Summary ................................... 261
Chapter 10: Mechanical Annealing Under Low-Amplitude Cyclic Loading ........................................ 263
10.1 Introduction ........................ 263
10.2 Cyclic Behavior of Collective Dislocations.......................264
10.3 Cyclic Instability of Dislocation Junction............................... 268
10.3.1 Glissile Dislocation Junction ............................... 268
10.3.2 Sessile Dislocation Junction ........................... 272
10.4 Cyclic Enhanced Dislocation Annihilation Mechanism ............................. 274
10.5 Dislocation Density In.uenced by Cyclic Slip Irreversibility ................................ 275
10.6 Critical Size for Mechanical Annealing................... 278
10.7 Summary .................................. 280
Chapter 11: Strain Rate Effect on Deformation of Single Crystals at Submicron Scale....................... 281
11.1 Introduction .......................................... 281
11.2 Strain Rate Effect on Flow Stress in Single-Crystal Copper Under Compression Loading...................................282
11.2.1 Strain Rate Effect of Submicron Copper Pillars Under Uniaxial Compression .................................... 283
11.2.2 Strain Rate Effect of Dislocation Evolution in Copper Cubes Under Hydrostatic Pressure............................289
11.3 Strain Rate Effect on Dynamic Deformation of Single-Crystal Copper Under Tensile Loading .................................... 298
11.3.1 Resolution of Discrete Dislocation Dynamics.......................299
11.3.2 Coupling Dislocation Dynamics Plasticity With Finite Element..........................................300
11.3.3 Model Description and Simulation Results ........................ 303
Contents
11.4 Shock-Induced Deformation and Dislocation Mechanisms in Single-Crystal Copper ........................... 313
11.4.1 Dynamic Mechanical Behavior Corresponding to Dislocation Microstructure....................................313
11.4.2 Dynamic Multiscale Discrete Dislocation Plasticity Model .................... 315
11.4.3 Coarse-Grained Homogeneous Nucleation Model ....... 316
11.4.4 Shock-Induced Plasticity at the Submicron Scale .......................... 320
11.4.5 Discussion and Conclusion.............................327
11.5 Summary ............................................. 328