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Summary
For more than thirty years, this text has been the definitive introduction to the thermodynamic principles of materials and their multitude of applications. New to this edition is a detailed discussion of acetylene combustion and a numerical explanation for the expansion of ideal gases, as well as additional worked examples covering a wide variety of applied thermodynamics concepts.
Author Biography
David R. Gaskell, School of Materials Engineering, Purdue University, West Lafayette, IN
Table of Contents
| Preface | p. xiii |
| Introduction and Definition of Terms | p. 1 |
| Introduction | p. 1 |
| The Concept of State | p. 1 |
| Simple Equilibrium | p. 4 |
| The Equation of State of an Ideal Gas | p. 5 |
| The Units of Energy and Work | p. 8 |
| Extensive and Intensive Properties | p. 8 |
| Phase Diagrams and Thermodynamic Components | p. 9 |
| Numerical Examples | p. 12 |
| The First Law of Thermodynamics | p. 15 |
| Introduction | p. 15 |
| The Relationship between Heat and Work | p. 16 |
| Internal Energy and the First Law of Thermodynamics | p. 17 |
| Constant-Volume Processes | p. 21 |
| Constant-Pressure Processes and the Enthalpy H | p. 21 |
| Heat Capacity | p. 21 |
| Reversible Adiabatic Processes | p. 25 |
| Reversible Isothermal Pressure or Volume Changes of an Ideal Gas | p. 27 |
| Summary | p. 28 |
| Numerical Examples | p. 29 |
| Problems | p. 34 |
| The Second Law of Thermodynamics | p. 37 |
| Introduction | p. 37 |
| Spontaneous or Natural Processes | p. 38 |
| Entropy and the Quantification of Irreversibility | p. 39 |
| Reversible Processes | p. 40 |
| An Illustration of Irreversible and Reversible Processes | p. 41 |
| Entropy and Reversible Heat | p. 43 |
| The Reversible Isothermal Compression of an Ideal Gas | p. 46 |
| The Reversible Adiabatic Expansion of an Ideal Gas | p. 47 |
| Summary Statements | p. 48 |
| The Properties of Heat Engines | p. 48 |
| The Thermodynamic Temperature Scale | p. 51 |
| The Second Law of Thermodynamics | p. 53 |
| Maximum Work | p. 55 |
| Entropy and the Criterion for Equilibrium | p. 57 |
| The Combined Statement of the First and Second Laws of Thermodynamics | p. 58 |
| Summary | p. 59 |
| Numerical Examples | p. 61 |
| Problems | p. 66 |
| The Statistical Interpretation of Entropy | p. 69 |
| Introduction | p. 69 |
| Entropy and Disorder on an Atomic Scale | p. 70 |
| The Concept of Microstate | p. 71 |
| Determination of the Most Probable Microstate | p. 72 |
| The Influence of Temperature | p. 76 |
| Thermal Equilibrium and the Boltzmann Equation | p. 78 |
| Heat Flow and the Production of Entropy | p. 79 |
| Configurational Entropy and Thermal Entropy | p. 80 |
| Summary | p. 83 |
| Numerical Examples | p. 84 |
| Problems | p. 86 |
| Auxiliary Functions | p. 87 |
| Introduction | p. 87 |
| The Enthalpy H | p. 88 |
| The Helmholtz Free Energy A | p. 89 |
| The Gibbs Free Energy G | p. 94 |
| Summary of the Equations for a Closed System | p. 95 |
| The Variation of the Composition and Size of the System | p. 95 |
| The Chemical Potential | p. 97 |
| Thermodynamic Relations | p. 98 |
| Maxwell's Equations | p. 98 |
| The Upstairs-Downstairs-Inside-Out Formula | p. 101 |
| The Gibbs-Helmholtz Equation | p. 102 |
| Summary | p. 103 |
| Example of the Use of the Thermodynamic Relations | p. 104 |
| Numerical Example | p. 105 |
| Problems | p. 107 |
| Heat Capacity, Enthalpy, Entropy, and the Third Law of Thermodyanmics | p. 109 |
| Introduction | p. 109 |
| Theoretical Calculation of the Heat Capacity | p. 110 |
| The Empirical Representation of Heat Capacities | p. 114 |
| Enthalpy as a Function of Temperature and Composition | p. 115 |
| The Dependence of Entropy on Temperature and the Third Law of Thermodynamics | p. 124 |
| Experimental Verification of the Third Law | p. 127 |
| The Influence of Pressure on Enthalpy and Entropy | p. 133 |
| Summary | p. 135 |
| Numerical Examples | p. 135 |
| Problems | p. 147 |
| Phase Equilibrium in a One-Component System | p. 149 |
| Introduction | p. 149 |
| The Variation of Gibbs Free Energy with Temperature at Constant Pressure | p. 150 |
| The Variation of Gibbs Free Energy with Pressure at Constant Temperature | p. 157 |
| Gibbs Free Energy as a Function of Temperature and Pressure | p. 159 |
| Equilibrium between the Vapor Phase and a Condensed Phase | p. 160 |
| Graphical Representation of Phase Equilibria in a One-Component System | p. 162 |
| Solid-Solid Equilibria | p. 168 |
| Summary | p. 171 |
| Numerical Examples | p. 172 |
| Problems | p. 175 |
| The Behavior of Gases | p. 177 |
| Introduction | p. 177 |
| The P-V-T Relationships of Gases | p. 177 |
| Deviations from Ideality and Equations of State for Real Gases | p. 180 |
| The van der Waals Gas | p. 182 |
| Other Equations of State for Nonideal Gases | p. 191 |
| The Thermodynamic Properties of Ideal Gases and Mixtures of Ideal Gases | p. 192 |
| The Thermodynamic Treatment of Nonideal Gases | p. 198 |
| Summary | p. 204 |
| Numerical Examples | p. 206 |
| Problems | p. 208 |
| The Behavior of Solutions | p. 211 |
| Introduction | p. 211 |
| Raoult's Law and Henry's Law | p. 211 |
| The Thermodynamic Activity of a Component in Solution | p. 215 |
| The Gibbs-Duhem Equation | p. 216 |
| The Gibbs Free Energy of Formation of a Solution | p. 218 |
| The Properties of Raoultian Ideal Solutions | p. 221 |
| Nonideal Solutions | p. 226 |
| Application of the Gibbs-Duhem Relation to the Determination of Activity | p. 229 |
| Regular Solutions | p. 240 |
| A Statistical Model of Solutions | p. 245 |
| Subregular Solutions | p. 252 |
| Summary | p. 254 |
| Numerical Examples | p. 257 |
| Problems | p. 259 |
| Gibbs Free Energy Composition and Phase Diagrams of Binary Systems | p. 263 |
| Introduction | p. 263 |
| Gibbs Free Energy and Thermodynamic Activity | p. 264 |
| The Gibbs Free Energy of Formation of Regular Solutions | p. 266 |
| Criteria for Phase Stability in Regular Solutions | p. 268 |
| Liquid and Solid Standard States | p. 273 |
| Phase Diagrams, Gibbs Free Energy, and Thermodynamic Activity | p. 283 |
| The Phase Diagrams of Binary Systems That Exhibit Regular Solution Behavior in the Liquid and Solid States | p. 292 |
| Summary | p. 298 |
| Numerical Example | p. 299 |
| Problems | p. 301 |
| Reactions Involving Gases | p. 305 |
| Introduction | p. 305 |
| Reaction Equilibrium in a Gas Mixture and the Equilibrium Constant | p. 306 |
| The Effect of Temperature on the Equilibrium Constant | p. 311 |
| The Effect of Pressure on the Equilibrium Constant | p. 312 |
| Reaction Equilibrium as a Compromise between Enthalpy and Entropy | p. 314 |
| Reaction Equilibrium in the System SO[subscript 2(g)]-SO[subscript 3(g)]-O[subscript 2(g)] | p. 316 |
| Equilibrium in H[subscript 2]O-H[subscript 2] and CO[subscript 2]-CO Mixtures | p. 321 |
| Summary | p. 323 |
| Numerical Examples | p. 324 |
| Problems | p. 335 |
| Reactions Involving Pure Condensed Phases and a Gaseous Phase | p. 337 |
| Introduction | p. 337 |
| Reaction Equilibrium in a System Containing Pure Condensed Phases and a Gas Phase | p. 338 |
| The Variation of the Standard Gibbs Free Energy Change with Temperature | p. 343 |
| Ellingham Diagrams | p. 346 |
| The Effect of Phase Transformations | p. 353 |
| The Oxides of Carbon | p. 358 |
| Graphical Representation of Equilibria in the System Metal-Carbon-Oxygen | p. 365 |
| Summary | p. 368 |
| Numerical Examples | p. 369 |
| Problems | p. 380 |
| Reaction Equilibria in Systems Containing Components in Condensed Solution | p. 383 |
| Introduction | p. 383 |
| The Criteria for Reaction Equilibrium in Systems Containing Components in Condensed Solution | p. 385 |
| Alternative Standard States | p. 393 |
| The Gibbs Phase Rule | p. 399 |
| Binary Systems Containing Compounds | p. 417 |
| Graphical Representation of Phase Equilibria | p. 429 |
| The Formation of Oxide Phases of Variable Composition | p. 437 |
| The Solubility of Gases in Metals | p. 446 |
| Solutions Containing Several Dilute Solutes | p. 450 |
| Summary | p. 460 |
| Numerical Examples | p. 462 |
| Problems | p. 470 |
| Phase Diagrams for Binary Systems in Pressure-Temperature-Composition Space | p. 475 |
| Introduction | p. 475 |
| A Binary System Exhibiting Complete Mutual Solubility of the Components in the Solid and Liquid States | p. 475 |
| A Binary System Exhibiting Complete Mutual Solubility in the Solid and Liquid States and Showing Minima on the Melting, Boiling, and Sublimation Curves | p. 480 |
| A Binary System Containing a Eutectic Equilibrium and Having Complete Mutual Solubility in the Liquid | p. 485 |
| A Binary System Containing a Peritectic Equilibrium and Having Complete Mutual Solubility in the Liquid State | p. 493 |
| Phase Equilibrium in a Binary System Containing an Intermediate [gamma] Phase That Melts, Sublimes, and Boils Congruently | p. 501 |
| Phase Equilibrium in a Binary System Containing an Intermediate [gamma] Phase That Melts and Sublimes Congruently and Boils Incongruently | p. 508 |
| Phase Equilibrium in a Binary System with a Eutectic and One Component That Exhibits Allotropy | p. 513 |
| A Binary Eutectic System in Which Both Components Exhibit Allotropy | p. 517 |
| Phase Equilibrium at Low Pressure: The Cadmium-Zinc System | p. 524 |
| Phase Equilibrium at High Pressure: The Na[subscript 2]O-Al[subscript 2]O[subscript 3]-2SiO[subscript 2]-SiO[subscript 2] System | p. 525 |
| Summary | p. 531 |
| Electrochemistry | p. 533 |
| Introduction | p. 533 |
| The Relationship between Chemical and Electrical Driving Forces | p. 535 |
| The Effect of Concentration on EMF | p. 540 |
| Formation Cells | p. 541 |
| Concentration Cells | p. 544 |
| The Temperature Coefficient of the EMF | p. 549 |
| Heat Effects | p. 551 |
| The Thermodynamics of Aqueous Solutions | p. 552 |
| The Gibbs Free Energy of Formation of Ions and Standard Reduction Potentials | p. 555 |
| Pourbaix Diagrams | p. 564 |
| Summary | p. 574 |
| Numerical Examples | p. 576 |
| Problems | p. 579 |
| Appendices | |
| Selected Thermodynamic and Thermochemical Data | p. 581 |
| Exact Differential Equations | p. 589 |
| The Generation of Auxiliary Functions as Legendre Transformations | p. 591 |
| Nomenclature | p. 599 |
| Answers | p. 603 |
| Index | p. 615 |
| Table of Contents provided by Ingram. All Rights Reserved. |
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