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A self instructive text for thermodynamics. This is the second edition of the title which can be supplemented by a solutions manual, OHT's and an IBM disk.

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CONTENTS
Preface = xvii
Nomenclature = xxi
1. BASIC CONCEPTS OF THERMODYNAMICS = 1
  1-1 Thermodynamics and Energy = 2
  1-2 A Note on Dimensions and Units = 3
  1-3 Closed and Open Systems = 7
  1-4 Forms of Energy = 8
  1-5 Properties of a System = 11
  1-6 State and Equilibrium = 12
  1-7 Processes and Cycles = 13
  1-8 The State postulate = 15
  1-9 Pressure = 16
  1-10 Temperature and the Zeroth Law of Thermodynamics = 20
  1-11 Summary = 23
  References and Suggested Reading = 24
  Problems = 25
2. PROPERTIES OF PURE SUBSTANCES = 31
  2-1 Pure Substance = 32
  2-2 Phases of a Pure Substance = 32
  2-3 Phase Change processes of Pure Substances = 34
  2-4 Property Diagrams for Phase Change processes = 37
  2-5 The P-υ-T Surface = 42
  2-6 Property Tables = 44
  2-7 The Ideal-Gas Equation of State = 53
  2-8 Compressibility Factor = 57
  2-9 Other Equations of State = 61
  2-10 Summary = 65
  References and Suggested Reading = 67
  Problems = 68
3. THE FIRST LAW OF THERMODYNAMICS―CLOSED SYSTEMS = 79
  3-1 Introduction to the First Law of Thermodynamics = 80
  3-2 Heat = 80
  3-3 Work = 81
  3-4 Mechanical Forms of Work = 86
  3-5 The First Law of Thermodynamics = 97
  3-6 A Systematic Approach to Problem Solving = 101
  3-7 Specific Heats = 108
  3-8 The Internal Energy, Enthalpy, and Specific Heats of Ideal Gases = 111
  3-9 The Internal Energy, Enthalpy, and Specific Heats of Solids and Liquids = 119
  3-10 Summary = 122
  References and Suggested Reading = 123
  Problems = 124
4. THE FIRST LAW OF THERMODYNAMICS―CONTROL VOLUMES = 141
  4-1 Thermodynamic Analysis of Control Volumes = 142
  4-2 The Steady-Flow Process = 147
  4-3 Steady-Flow Engineering Devices = 153
  4-4 Unsteady-Flow Processes = 167
  4-5 Summary = 178
  References and Suggested Reading = 180
  Problems = 181
5. THE SECOND LAW OF THERMODYNAMICS = 199
  5-1 Introduction to the Second Law of Thermodynamics = 200
  5-2 Thermal-Energy Reservoirs = 201
  5-3 Heat Engines = 202
  5-4 Refrigerators and Heat Pumps = 208
  5-5 Perpetual-Motion Machines = 214
  5-6 Reversible and Irreversible processes = 216
  5-7 The Carnot Cycle = 221
  5-8 The Carnot Principles = 224
  5-9 The Absolute Thermodynamic Temperature Scale = 225
  5-10 The Carnot Heat Engine = 227
  5-11 The Carnot Refrigerator and Heat pump = 230
  5-12 Summary = 232
  References and Suggested Reading = 234
  Problems = 234
6. ENTROPY = 249
  6-1 The Clausius Inequality = 250
  6-2 Entropy = 252
  6-3 The Increase in Entropy Principle = 256
  6-4 Causes of Entropy Change = 262
  6-5 What Is Entropy? = 263
  6-6 Property Diagrams involving Entropy = 266
  6-7 The T ds Relations = 270
  6-8 The Entropy Change of Pure Substances = 271
  6-9 The Entropy Change of Solids and Liquids = 276
  6-10 The Entropy Change of Ideal Gases = 279
  6-11 The Reversible Steady-Flow Work = 286
  6-12 Minimizing the Compressor Work = 290
  6-13 Adiabatic Efficiencies of Some Steady-Flow Devices = 294
  6-14 Summary = 302
  References and Suggested Reading = 306
  Problems = 307
7. SECOND-LOW ANALYSIS OF ENGINEERING SYSTEMS = 325
  7-1 Availability = 326
  7-2 Reversible Work and Irreversibility = 329
  7-3 The Second-Law Efficiency = 333
  7-4 Second-Law Analysis of Closed Systems = 335
  7-5 Second-Law Analysis of Steady-Flow Systems = 345
  7-6 Second-Law Analysis of Unsteady-Flow Systems = 349
  7-7 Summary = 355
  References and Suggested Reading = 358
  Problems = 358
8. GAS POWER CYCLES = 373
  8-1 Basic Considerations in the Analysis of Power Cycles = 375
  8-2 The Carnot Cycle and Its Value in Engineering = 377
  8-3 Air-Standard Assumptions = 379
  8-4 A Brief Overview of Reciprocating Engines = 380
  8-5 Otto Cycle = 381
  8-6 Diesel Cycle = 387
  8-7 Stirling and Ericsson Cycles = 391
  8-8 Brayton Cycle = 396
  8-9 The Brayton Cycle with Regeneration = 402
  8-10 The Brayton Cycle with Intercooling, Reheating, and Regeneration = 404
  8-11 The Ideal Jet-Propulsion Cycle = 408
  8-12 Second-Law Analysis of Gas Power Cycles = 414
  8-13 Summary = 416
  References and Suggested Reading = 419
  Problems = 420
9. VAPOR AND COMBINED POWER CYCLES = 439
  9-1 The Carnot Vapor Cycle = 440
  9-2 Rankine Cycle = 441
  9-3 Deviation of Actual Vapor Power Cycles from the Idealized Ones = 444
  9-4 How Can We Increase the Efficiency of the Rankine Cycle? = 447
  9-5 The Ideal Reheat Rankine Cyrle = 451
  9-6 The Ideal Regenerative Rankine Cycle = 455
  9-7 Second-Law Analysis of Vapor Power Cycles = 462
  9-8 Cogeneration = 464
  9-9 Binary Vapor Cycles = 469
  9-10 Combined Gas-Vapor Power Cycles = 471
  9-11 Summary = 474
  References and Suggested Reading = 475
  Problems = 476
10. REFRIGERATION CYCLES = 493
  10-1 Refrigerators and Heat Pumps = 494
  10-2 The Reversed Carnot Cycle = 495
  10-3 The Ideal Vapor-Compression Refrigeration Cycle = 497
  10-4 Actual Vapor-Compression Refrigeration Cycle = 500
  10-5 Selecting the Right Refrigerant = 503
  10-6 Heat Pump Systems = 504
  10-7 Innovative Vapor-Compression Refrigeration Systems = 505
  10-8 Gas Refrigeration Cycle = 513
  10-9 Absorption Refrigeration Systems = 516
  10-10 Thermoelectric Power Generation and Refrigeration Systems = 519
  10-11 Summary = 521
  References and Suggested Reading = 522
  Problems = 523
11. THERMODYNAMIC PROPERTY RELATIONS = 535
  11-1 A Little Math―Partial Derivatives and Associated Relations = 536
  11-2 The Maxwell Relations = 542
  11-3 The Clapeyron Equation = 543
  11-4 General Relations for du, dh, ds, C v , and C p = 546
  11-5 The Joule-Thompson Cofficient = 553
  11-6 The Δh, Δu, and Δs of Real Gases = 555
  11-7 Summary = 561
  References and Suggested Reading = 563
  Problems = 563
12. GAS MIXTURES 571
  12-1 The Composition of a Gas Mixture―Mass and Mole Fractions = 572
  12-2 P-υ-T Behavior of Gas Mixtures = 574
  12-3 Properties of Gas Mixtures = 578
  12-4 Summary = 586
  References and Suggested Reading = 587
  Problems = 588
13. GAS-VAPOR MIXTURES AND AIR CONDITIONING = 595
  13-1 Dry and Atmospheric Air = 596
  13-2 Specific and Relative Humidity of Air = 597
  13-3 Dew-Point Temperature = 599
  13-4 Adiabatic Saturation and Wet-Bulb Temperatures = 601
  13-5 The Psychrometric Chart = 604
  13-6 Human Comfort and Air Conditioning = 605
  13-7 Air Conditioning Processes = 607
  13-8 Summary = 621
  References and Suggested Reading = 623
  Problems = 623
14. CHEMICAL REACTIONS = 635
  14-1 Fuels and Combustion = 636
  14-2 Theoretical and Actual Combustion Processes = 639
  14-3 Enthalpy of Formation and Enthalpy of Combustion = 644
  14-4 Firs Law Analysis of Reacting Systems = 648
  14-5 Adiabatic Flame Temperature = 652
  14-6 Entropy Change of Reacting Systems = 654
  14-7 Second Law Analysis of Reacting Systems = 656
  14-8 Summary = 663
  References and Suggested Reading = 665
  Problems = 666
15. CHEMICAL AND PHASE EQUILIBRIUM = 677
  15-1 Criteria for Chemical Equilibrium = 678
  15-2 The Equilibrium Constant for Ideal Gas mixtures = 681
  15-3 Some Remarks About the K p of Ideal Gas Mixtures = 683
  15-4 Chemical Equilibrium for Simultaneous Reactions = 688
  15-5 The Variation of K p with Temperature = 689
  15-6 Phase Equilibrium = 691
  15-7 Summary = 695
  References and Suggested Reading = 697
  Problems = 697
16. THERMODYNAMICS OF HIGH-SPEED FLUID FLOW = 705
  16-1 Stagnation Properties = 706
  16-2 Velocity of Sound and mach number = 710
  16-3 One-Dimensional Isentropic Flow = 713
  16-4 Isentropic Flow through Nozzles = 721
  16-5 Normal Shocks in Nozzle Flow = 730
  16-6 Flow through Actual Nozzles and Diffusers = 736
  16-7 Steam nozzles = 742
  16-8 Summary = 746
  References and Suggested Reading = 749
  Problems = 750
Index = 859