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BL
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| Record Number
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878285
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| Uniform Title
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Chemical and engineering thermodynamics
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| Main Entry
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Sandler, Stanley I.,1940-
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| Title & Author
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Chemical, biochemical and engineering thermodynamics /\ Stanley I. Sandler, University of Delaware.
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| Edition Statement
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Fifth edition.
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| Publication Statement
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Hoboken, NJ :: Wiley,, [2017]
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| Page. NO
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xiv, 1007 pages :: illustrations ;; 26 cm
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| ISBN
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047050479X
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: 9780470504796
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9781119321286
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9781119343776
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| Notes
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Revised edition of: Chemical and engineering thermodynamics.
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| Bibliographies/Indexes
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Includes bibliographical references and index.
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| Contents
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Machine generated contents note: Instructional Objectives for Chapter 1 -- Important Notation Introduced in This Chapter -- 1.1. The Central Problems of Thermodynamics -- 1.2.A System of Units -- 1.3. The Equilibrium State -- 1.4. Pressure, Temperature, and Equilibrium -- 1.5. Heat, Work, and the Conservation of Energy -- 1.6. Specification of the Equilibrium State; Intensive and Extensive Variables; Equations of State -- 1.7.A Summary of Important Experimental Observations -- 1.8.A Comment on the Development of Thermodynamics -- Problems -- Instructional Objectives for Chapter 2 -- Important Notation Introduced in This Chapter -- 2.1.A General Balance Equation and Conserved Quantities -- 2.2. Conservation of Mass for a Pure Fluid -- 2.3. The Mass Balance Equations for a Multicomponent System with a Chemical Reaction -- 2.4. The Microscopic Mass Balance Equations in Thermodynamics and Fluid Mechanics (Optional -- only on the website for this book) -- Problems.
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Note continued: 14.3. Overall Reactor Balance Equations and the Adiabatic Reaction Temperature -- 14.4. Thermodynamics of Chemical Explosions -- 14.5. Maximum Useful Work and Availability in Chemically Reacting Systems -- 14.6. Introduction to Electrochemical Processes -- 14.7. Fuel Cells and Batteries -- Problems -- Instructional Objectives for Chapter 15 -- Notation Introduced in This Chapter -- 15.1. Solubilities of Weak Acids, Weak Bases, and Amino Acids as a Function of pH -- 15.2. The Solubility of Amino Acids and Proteins as a function of Ionic Strength and Temperature -- 15.3. Binding of a Ligand to a Substrate -- 15.4. Some Other Examples of Biochemical Reactions -- 15.5. The Denaturation of Proteins -- 15.6. Coupled Biochemical Reactions: The ATP-ADP Energy Storage and Delivery Mechanism -- 15.7. Thermodynamic Analysis of Fermenters and Other Bioreactors -- 15.8. Gibbs-Donnan Equilibrium and Membrane Potentials -- 15.9. Protein Concentration in an Ultracentrifuge.
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Note continued: 5.2. Power Generation and Refrigeration Cycles -- 5.3. Thermodynamic Efficiencies -- 5.4. The Thermodynamics of Mechanical Explosions -- Problems -- Instructional Objectives for Chapter 6 -- Notation Introduced in this Chapter -- 6.1. Some Mathematical Preliminaries -- 6.2. The Evaluation of Thermodynamic Partial Derivatives -- 6.3. The Ideal Gas and Absolute Temperature Scales -- 6.4. The Evaluation of Changes in the Thermodynamic Properties of Real Substances Accompanying a Change of State -- 6.5. An Example Involving the Change of State of a Real Gas -- 6.6. The Principle of Corresponding States -- 6.7. Generalized Equations of State -- 6.8. The Third Law of Thermodynamics -- 6.9. Estimation Methods for Critical and Other Properties -- 6.10. Sonic Velocity -- 6.11. More About Thermodynamic Partial Derivatives (Optional -- only on website for this book) -- Problems -- Instructional Objectives for Chapter 7 -- Notation Introduced in This Chapter.
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Note continued: 7.1. The Criteria for Equilibrium -- 7.2. Stability of Thermodynamic Systems -- 7.3. Phase Equilibria: Application of the Equilibrium and Stability Criteria to the Equation of State -- 7.4. The Molar Gibbs Energy and Fugacity of a Pure Component -- 7.5. The Calculation of Pure Fluid-Phase Equilibrium: The Computation of Vapor Pressure from an Equation of State -- 7.6. Specification of the Equilibrium Thermodynamic State of a System of Several Phases: The Gibbs Phase Rule for a One-Component System -- 7.7. Thermodynamic Properties of Phase Transitions -- 7.8. Thermodynamic Properties of Small Systems, or Why Subcooling and Superheating Occur -- Problems -- Instructional Objectives for Chapter 8 -- Notation Introduced in This Chapter -- 8.1. The Thermodynamic Description of Mixtures -- 8.2. The Partial Molar Gibbs Energy and the Generalized Gibbs-Duhem Equation -- 8.3.A Notation for Chemical Reactions -- 8.4. The Equations of Change for a Multicomponent System.
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Note continued: 8.5. The Heat of Reaction and a Convention for the Thermodynamic Properties of Reacting Mixtures -- 8.6. The Experimental Determination of the Partial Molar Volume and Enthalpy -- 8.7. Criteria for Phase Equilibrium in Multicomponent Systems -- 8.8. Criteria for Chemical Equilibrium, and Combined Chemical and Phase Equilibrium -- 8.9. Specification of the Equilibrium Thermodynamic State of a Multicomponent, Multiphase System; the Gibbs Phase Rule -- 8.10.A Concluding Remark -- Problems -- Instructional Objectives for Chapter 9 -- Notation Introduced in This Chapter -- 9.1. The Ideal Gas Mixture -- 9.2. The Partial Molar Gibbs Energy and Fugacity -- 9.3. Ideal Mixture and Excess Mixture Properties -- 9.4. Fugacity of Species in Gaseous, Liquid, and Solid Mixtures -- 9.5. Several Correlative Liquid Mixture Activity Coefficient Models -- 9.6. Two Predictive Activity Coefficient Models -- 9.7. Fugacity of Species in Nonsimple Mixtures.
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Note continued: 9.8. Some Comments on Reference and Standard States -- 9.9.Combined Equation-of-State and Excess Gibbs Energy Model -- 9.10. Electrolyte Solutions -- 9.11. Choosing the Appropriate Thermodynamic Model -- Appendix A9.1 A Statistical Mechanical Interpretation of the Entropy of Mixing in an Ideal Mixture (Optional -- only on the website for this book) -- Appendix A9.2 Multicomponent Excess Gibbs Energy (Activity Coefficient) Models -- Appendix A9.3 The Activity Coefficient of a Solvent in an Electrolyte Solution -- Problems -- Instructional Objectives for Chapter 10 -- Notation Introduced in This Chapter -- 10.0. Introduction to Vapor-Liquid Equilibrium -- 10.1. Vapor-Liquid Equilibrium in Ideal Mixtures -- Problems for Section 10.1 -- 10.2. Low-Pressure Vapor-Liquid Equilibrium in Nonideal Mixtures -- Problems for Section 10.2 -- 10.3. High-Pressure Vapor-Liquid Equilibria Using Equations of State (0-0 Method) -- Problems for Section 10.3.
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Note continued: Instructional Objectives for Chapter 11 -- Notation Introduced in This Chapter -- 11.1. The Solubility of a Gas in a Liquid -- Problems for Section 11.1 -- 11.2. Liquid-Liquid Equilibrium -- Problems for Section 11.2 -- 11.3. Vapor-Liquid-Liquid Equilibrium -- Problems for Section 11.3 -- 11.4. The Partitioning of a Solute Among Two Coexisting Liquid Phases; The Distribution Coefficient -- Problems for Section 11.4 -- 11.5. Osmotic Equilibrium and Osmotic Pressure -- Problems for Section 11.5 -- Instructional Objectives for Chapter 12 -- Notation Introduced in This Chapter -- 12.1. The Solubility of a Solid in a Liquid, Gas, or Supercritical Fluid -- Problems for Section 12.1 -- 12.2. Partitioning of a Solid Solute Between Two Liquid Phases -- Problems for Section 12.2 -- 12.3. Freezing-Point Depression of a Solvent Due to the Presence of a Solute; the Freezing Point of Liquid Mixtures -- Problems for Section 12.3 -- 12.4. Phase Behavior of Solid Mixtures.
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Note continued: Instructional Objectives for Chapter 3 -- Notation Introduced in This Chapter -- 3.1. Conservation of Energy -- 3.2. Several Examples of Using the Energy Balance -- 3.3. The Thermodynamic Properties of Matter -- 3.4. Applications of the Mass and Energy Balances -- 3.5. Conservation of Momentum -- 3.6. The Microscopic Energy Balance (Optional -- only on website for this book) -- Problems -- Instructional Objectives for Chapter 4 -- Notation Introduced in This Chapter -- 4.1. Entropy: A New Concept -- 4.2. The Entropy Balance and Reversibility -- 4.3. Heat, Work, Engines, and Entropy -- 4.4. Entropy Changes of Matter -- 4.5. Applications of the Entropy Balance -- 4.6. Availability and the Maximum Useful Shaft Work that can be obtained In a Change of State -- 4.7. The Microscopic Entropy Balance (Optional -- only on website for this book) -- Problems -- Instructional Objectives for Chapter 5 -- Notation Introduced in this Chapter -- 5.1. Liquefaction.
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Note continued: Problems -- Appendix A.I Conversion Factors For Si Units -- Appendix A. II The Molar Heat Capacities Of Gases In The Ideal Gas (Zero Pressure) State -- Appendix A. III The Thermodynamic Properties Of Water And Steam -- Appendix A. IV Enthalpies And Free Energies Of Formation -- Appendix A.V Heats Of Combustion -- Appendix B.I Windows-Based Visual Basic Programs -- Appendix B. II Dos-Based Basic Programs -- Appendix B. III Mathcad Worksheets -- Appendix B. IV Matlab Programs.
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Note continued: Problems for Section 12.4 -- 12.5. The Phase Behavior Modeling of Chemicals in the Environment -- Problems for Section 12.5 -- 12.6. Process Design and Product Design -- Problems for Section 12.6 -- 12.7. Concluding Remarks on Phase Equilibria -- Instructional Objectives for Chapter 13 -- Important Notation Introduced in This Chapter -- 13.1. Chemical Equilibrium in a Single-Phase System -- 13.2. Heterogeneous Chemical Reactions -- 13.3. Chemical Equilibrium When Several Reactions Occur in a Single Phase -- 13.4.Combined Chemical and Phase Equilibrium -- 13.5. Ionization and the Acidity of Solutions -- 13.6. Ionization of Biochemicals -- 13.7. Partitioning of Amino Acids and Proteins Between Two Liquids -- Problems -- Instructional Objectives for Chapter 14 -- Notation Introduced in This Chapter -- 14.1. The Balance Equations for a Tank-Type Chemical Reactor -- 14.2. The Balance Equations for a Tubular Reactor.
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| Subject
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Biochemical engineering, Textbooks.
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Chemical engineering, Textbooks.
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Thermodynamics, Textbooks.
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Biochemical engineering.
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| Subject
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Chemical engineering.
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| Subject
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Thermodynamics.
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| Dewey Classification
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541/.369
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| LC Classification
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QD504.S25 2017
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