相平衡、相圖和相變——其熱力學基礎（第二版）（英文影印版）

本書主要內容為現代計算機套用觀點下的熱力學基本原理。 化學平衡和化學變化的理論基礎也是本書的內容之一，其重點在於相圖的性質。本書從基本原理出發，討論延及多相的系統。第二版新增加的內容包括不可逆熱力學、極值原理和表面、界面熱力學等等。 平衡條件的理論刻畫、系統的平衡狀態和達到平衡時的變化都以圖解的形式給出。 本書適合材料科學與工程領域的研究人員、研究生和高年級本科生閱讀。

Preface to second edition page xii

Preface to first edition xiii

1 Basic concepts of thermodynamics 1

1.1 External state variables 1

1.2 Internal state variables 3

1.3 The first law of thermodynamics 5

1.4 Freezing-in conditions 9

1.5 Reversible and irreversible processes 10

1.6 Second law of thermodynamics 13

1.7 Condition of internal equilibrium 17

1.8 Driving force 19

1.9 Combined first and second law 21

1.10 General conditions of equilibrium 23

1.11 Characteristic state functions 24

1.12 Entropy 26

2 Manipulation of thermodynamic quantities 30

2.1 Evaluation of one characteristic state function from another 30

2.2 Internal variables at equilibrium 31

2.3 Equations of state 33

2.4 Experimental conditions 34

2.5 Notation for partial derivatives 37

2.6 Use of various derivatives 38

2.7 Comparison between CV and CP 40

2.8 Change of independent variables 41

2.9 Maxwell relations 43

3 Systems with variable composition 45

3.1 Chemical potential 45

3.2 Molar and integral quantities 46

3.3 More about characteristic state functions 48

3.4 Additivity of extensive quantities. Free energy and exergy 51

3.5 Various forms of the combined law 52

3.6 Calculation of equilibrium 54

3.7 Evaluation of the driving force 56

3.8 Driving force for molecular reactions 58

3.9 Evaluation of integrated driving force as function of T or P 59

3.10 Effective driving force 60

4 Practical handling of multicomponent systems 63

4.1 Partial quantities 63

4.2 Relations for partial quantities 65

4.3 Alternative variables for composition 67

4.4 The lever rule 70

4.5 The tie-line rule 71

4.6 Different sets of components 74

4.7 Constitution and constituents 75

4.8 Chemical potentials in a phase with sublattices 77

5 Thermodynamics of processes 80

5.1 Thermodynamic treatment of kinetics of internal processes 80

5.2 Transformation of the set of processes 83

5.3 Alternative methods of transformation 85

5.4 Basic thermodynamic considerations for processes 89

5.5 Homogeneous chemical reactions 92

5.6 Transport processes in discontinuous systems 95

5.7 Transport processes in continuous systems 98

5.8 Substitutional diffusion 101

5.9 Onsager’s extremum principle 104

6 Stability 108 6.1 Introduction 108

6.2 Some necessary conditions of stability 110

6.3 Sufficient conditions of stability 113

6.4 Summary of stability conditions 115

6.5 Limit of stability 116

6.6 Limit of stability against fluctuations in composition 117

6.7 Chemical capacitance 120

6.8 Limit of stability against fluctuations of internal variables 121

6.9 Le Chatelier’s principle 123

7 Applications of molar Gibbs energy diagrams 126

7.1 Molar Gibbs energy diagrams for binary systems 126

7.2 Instability of binary solutions 131

7.3 Illustration of the Gibbs–Duhem relation 132

7.4 Two-phase equilibria in binary systems 135

7.5 Allotropic phase boundaries 137

7.6 Effect of a pressure difference on a two-phase equilibrium 138

7.7 Driving force for the formation of a new phase 142

7.8 Partitionless transformation under local equilibrium 144

7.9 Activation energy for a fluctuation 147

7.10 Ternary systems 149 7.11 Solubility product 151

8 Phase equilibria and potential phase diagrams 155

8.1 Gibbs’ phase rule 155

8.2 Fundamental property diagram 157

8.3 Topology of potential phase diagrams 162

8.4 Potential phase diagrams in binary and multinary systems 166

8.5 Sections of potential phase diagrams 168

8.6 Binary systems 170

8.7 Ternary systems 173

8.8 Direction of phase fields in potential phase diagrams 177

8.9 Extremum in temperature and pressure 181

9 Molar phase diagrams 185

9.1 Molar axes 185

9.2 Sets of conjugate pairs containing molar variables 189

9.3 Phase boundaries 193

9.4 Sections of molar phase diagrams 195

9.5 Schreinemakers’ rule 197

9.6 Topology of sectioned molar diagrams 201

10 Projected and mixed phase diagrams 205

10.1 Schreinemakers’ projection of potential phase diagrams 205

10.2 The phase field rule and projected diagrams 208

10.3 Relation between molar diagrams and Schreinemakers’ projected diagrams 212

10.4 Coincidence of projected surfaces 215

10.5 Projection of higher-order invariant equilibria 217

10.6 The phase field rule and mixed diagrams 220

10.7 Selection of axes in mixed diagrams 223

10.8 Konovalov’s rule 226

10.9 General rule for singular equilibria 229

11 Direction of phase boundaries 233

11.1 Use of distribution coefficient 233

11.2 Calculation of allotropic phase boundaries 235

11.3 Variation of a chemical potential in a two-phase field 238

11.4 Direction of phase boundaries 240

11.5 Congruent melting points 244

11.6 Vertical phase boundaries 248

11.7 Slope of phase boundaries in isothermal sections 249

11.8 The effect of a pressure difference between two phases 251

12 Sharp and gradual phase transformations 253

12.1 Experimental conditions 253

12.2 Characterization of phase transformations 255

12.3 Microstructural character 259

12.4 Phase transformations in alloys 261

12.5 Classification of sharp phase transformations 262

12.6 Applications of Schreinemakers’ projection 266

12.7 Scheil’s reaction diagram 270

12.8 Gradual phase transformations at fixed composition 272

12.9 Phase transformations controlled by a chemical potential 275

13 Transformations in closed systems 279

13.1 The phase field rule at constant composition 279

13.2 Reaction coefficients in sharp transformations for p = c + 1 280

13.3 Graphical evaluation of reaction coefficients 283

13.4 Reaction coefficients in gradual transformations for p = c 285

13.5 Driving force for sharp phase transformations 287

13.6 Driving force under constant chemical potential 291

13.7 Reaction coefficients at constant chemical potential 294

13.8 Compositional degeneracies for p = c 295

13.9 Effect of two compositional degeneracies for p = c . 1 299

14 Partitionless transformations 302

14.1 Deviation from local equilibrium 302

14.2 Adiabatic phase transformation 303

14.3 Quasi-adiabatic phase transformation 305

14.4 Partitionless transformations in binary system 308

14.5 Partial chemical equilibrium 311

14.6 Transformations in steel under quasi-paraequilibrium 315

14.7 Transformations in steel under partitioning of alloying elements 319

15 Limit of stability and critical phenomena 322

15.1 Transformations and transitions 322

15.2 Order–disorder transitions 325

15.3 Miscibility gaps 330

15.4 Spinodal decomposition 334