Thermodynamics : an engineering approach / Yunus A. Çengel, Michael A. Boles.

Contents;

CHAPTER ONE : BASIC CONCEPTS OF THERMODYNAMICS
1.1 Thermodynamics and Energy
1.2 A Note on Dimensions and Units
1.3 Closed and Open Systems
1.4 Properties of a System
1.5 State and Equilibrium
Etc.

CHAPTER TWO : PROPERTIES OF PURE SUBSTANCE
2.1 Pure Substance
2.2 Phases of a Pure Substance
2.3 Phase-Change Processes of Pure Substances
2.4 Property Diagram for Phase-Change Processes
2.5 Property Tables
Etc.

CHAPTER THREE : ENERGY TRANSFER BY HEAT , WORK, AND MASS
3.1 Heat Transfer
3.2 Energy Transfer by Work
3.3 Mechanical Forms of Work
3.4 Nonmechanical Forms of Work
3.5 Conservation of Mass Principle
Etc.

CHAPTER FOUR: THE FIRST LAW OF THERMODYNAMICS
4.1 The First Law of Thermodynamics
4.2 Energy Balance for Closed Systems
4.3 Energy Balance for Steady- Flow Systems
4.4 Some Steady-Flow Engineering Devices
4.5 Energy Balance for Unsteady-Flow Processes
Etc.

CHAPTER FIVE:THE SECOND LAW OF THERMODYNAMICS
5.1 Introduction to the Second Law
5.2 Thermal Energy Reserviors
5.3 Heat Engines
5.4 Energy Conversion Efficiencies
5.5 Refrigerators and Heat Pumps
Etc.

CHAPTER SIX: ENTROPY
6.1 Entropy
6.2 The Increase of Entropy Principles
6.2 Entropy Change of Pure Substances
6.4 Isentropic Proceses
6.5 Property Diagrams Involving Entropy
Etc.

CHAPTER SEVEN: ENERGY : A MEASURE OF WORK POTENTIAL
7.1 Energy: Work Potential of Energy
7.2 Reversible Work and Irreversibility
7.3 Second-Law Efficiency,
7.4 Energy Change of a System
7.5 Energy Transfer By Heat, Work, and Mass
Etc.

CHAPTER EIGHT: GAS POWER CYCLES
8.1 Basic Considerations in the Analysis of Power Cycles
8.2 The Carnot Cycle and Its Value in Engineering
8.3 Air-Standard Assumptions
8.4 An Overview of Reciprocating Engines
8.5 Otto Cycle: The Ideal Cycle for Spark-Ignition Engines
Etc.

CHAPTER NINE: VAPOR AND COMBINED POWER CYCLES
9.1 The Carnot Vapor Cycle
9.2 Rankine Cycle: The Ideal Cycle for Vapor Power Cycles
9.3 Deviation of Actual Vapor Power Cycles from Idealized Ones
9.4 How Can we Increase the Efficiency of the Rankine Cycle?
9.5 The Ideal Reheat Rankine Cycle
Etc.

CHAPTER TEN: REFRIGERATION CYCLES
10.1 Refrigerators and Heat Pumps
10.2 The Reversed Carnot Cycle
10.3 The Ideal Vapor-Compression Refrigeration Cycle
10.4 Actual Vapor-Compression Refrigeration Cycle
10.5 Selecting the Right Refrigerant
Etc.

CHAPTER ELEVEN: THERMODYNAMIC PROPERTY RELATIONS
11.1 A Little Math - Partial Derivatives and Associated Relations
11.2 The Maxwell Relations
11.3 The Clapeyron Equation
11.4 General Relations for du, dh, Cv, and Cp
11.5 The Joule - Thomson Coefficient
Etc.

CHAPTER TWELVE: GAS MIXTURES
12.1 Composition of a Gas Mixture: Gas and Mole Fractions
12.2 P-v-T Behavior of Gas Mixtures: Ideal and Real Gases
12.3 Properties of Gas Mixtures: Ideal and Real Gases

CHAPTER THIRTEEN: GAS-VAPOR MIXTURES AND AIR-CONDITIONING
13.1 Dry and Atmospheric Air
13.2 Specific and Relative Humidity of Air
13.3 Dew-Point Temperature
13.4 Adiabatic Saturation and Wet-Bulb Temperatures
13.5 The Psychrometric Charts
Etc.

CHAPTER ROURTEEN: CHEMICAL REACTIONS
14.1 Fuels and Combustion
14.2 Theoretical and Actual Combustion Processes
14.3 Enthalpy of Formation and Enthalpy of Combustion
14.4 First-Law Analysis of Reacting Systems
14.5 Adiabatic Flame Temperature
Etc.

CHAPTER FIFTEEN: CHEMICAL AND PHASE EQUILIBRIUM
15.1 Criterion for Chemical Equilibrium
15.2 The Equilibrium Constant for Ideal-Gas Mixtures
15.3 Some Remarks about the Kp of Ideal-Gas Mixtures
15.5 Chemical Equilibrium for Simultaneous Reactions
Etc.

CHAPTER SIXTEEN: THERMODYNAMICS OF HIGH-SPEED GAS FLOW
16.1 Stagnation Properties
16.2 Velocity of Sound and Mach Number
16.3 One-Dimensioal Isentropic Flow
16.4 Isentropic Flow Through Nozzles
16.5 Normal Shocks in Nozzels and Diffusers
Etc.

Index : p. 926- 930