Hoboken, NJ, : Wiley, c2010

1-282-49136-9

9786612491368

0-470-54994-7

0-470-54995-5

1 online resource (317 p.)

Wiley series on processing engineering materials

OatesW. Alan <1931->

620.1/1296

620.1696

Materials - Thermal properties

Thermodynamics

Inglese

Includes index.

MATERIALS THERMODYNAMICS; Contents; Preface; Quantities, Units, and Nomenclature; 1 Review of Fundamentals; 1.1 Systems, Surroundings, and Work; 1.2 Thermodynamic Properties; 1.3 The Laws of Thermodynamics; 1.4 The Fundamental Equation; 1.5 Other Thermodynamic Functions; 1.5.1 Maxwell's Equations; 1.5.2 Defining Other Forms of Work; 1.6 Equilibrium State; Exercises; 2 Thermodynamics of Unary Systems; 2.1 Standard State Properties; 2.2 The Effect of Pressure; 2.2.1 Gases; 2.2.2 Condensed Phases; 2.3 The Gibbs-Duhem Equation; 2.4 Experimental Methods; Exercises

3 Calculation of Thermodynamic Properties of Unary Systems3.1 Constant-Pressure/Constant-Volume Conversions; 3.2 Excitations in Gases; 3.2.1 Perfect Monatomic Gas; 3.2.2 Molecular Gases; 3.3 Excitations in Pure Solids; 3.4 The Thermodynamic Properties of a Pure Solid; 3.4.1 Inadequacies of the Model; Exercises; 4 Phase Equilibria in Unary Systems; 4.1 The Thermodynamic Condition for Phase Equilibrium; 4.2 Phase Changes; 4.2.1 The Slopes of Boundaries in Phase Diagrams; 4.2.2 Gibbs Energy Changes for Phase Transformations; 4.3 Stability and Critical Phenomena; 4.4 Gibbs's

Phase Rule; Exercises

5 Thermodynamics of Binary Solutions I: Basic Theory and Application to Gas Mixtures5.1 Expressing Composition; 5.2 Total (Integral) and Partial Molar Quantities; 5.2.1 Relations between Partial and Integral Quantities; 5.2.2 Relation between Partial Quantities: the Gibbs-Duhem Equation; 5.3 Application to Gas Mixtures; 5.3.1 Partial Pressures; 5.3.2 Chemical Potentials in Perfect Gas Mixtures; 5.3.3 Real Gas Mixtures: Component Fugacities and Activities; Exercises; 6 Thermodynamics of Binary Solutions II: Theory and Experimental Methods; 6.1 Ideal Solutions; 6.1.1 Real Solutions

6.1.2 Dilute Solution Reference States6.2 Experimental Methods; 6.2.1 Chemical Potential Measurements; Exercises; 7 Thermodynamics of Binary Solutions III: Experimental Results and Their Analytical Representation; 7.1 Some Experimental Results; 7.1.1 Liquid Alloys; 7.1.2 Solid Alloys; 7.2 Analytical Representation of Results for Liquid or Solid Solutions; Exercises; 8 Two-Phase Equilibrium I: Theory; 8.1 Introduction; 8.2 Criterion for Phase Equilibrium Between Two Specified Phases; 8.2.1 Equilibrium between Two Solution Phases

8.2.2 Equilibrium between a Solution Phase and a Stoichiometric Compound Phase8.3 Gibbs's Phase Rule; Exercises; 9 Two-Phase Equilibrium II: Example Calculations; Exercises; 10 Binary Phase Diagrams: Temperature-Composition Diagrams; 10.1 True Phase Diagrams; 10.2 T -x(i) Phase Diagrams for Strictly Regular Solutions; 10.2.1 Some General Observations; 10.2.2 More on Miscibility Gaps; 10.2.3 The Chemical Spinodal; 10.3 Polymorphism; Exercises; 11 Binary Phase Diagrams: Temperature-Chemical Potential Diagrams; 11.1 Some General Points; Exercises; 12 Phase Diagram Topology

12.1 Gibbs's Phase Rule

A timely, applications-driven text in thermodynamics Materials Thermodynamics provides both students and professionals with the in-depth explanation they need to prepare for the real-world application of thermodynamic tools. Based upon an actual graduate course taught by the authors, this class-tested text covers the subject with a broader, more industry-oriented lens than can be found in any other resource available. This modern approach: Reflects changes rapidly occurring in society at large-from the impact of computers on the teaching of thermodynamics in materials