Joseph F. (Chem Solve, Inc.) Zemaitis,
JF Zemaitis,
Diane M. (OLI Systems, Inc.) Clark,
Marshall (OLI Systems, Inc.) Rafal,
Noel C. (E.I. duPont de Nemours & Co., Inc.) Scrivner
e.a.
Handbook of Aqueous Electrolyte Thermodynamics – Theory and Application
Theory & Application
Gebonden Engels 1986 9780816903504
Verwachte levertijd ongeveer 9 werkdagen
Samenvatting
Expertise in electrolyte systems has become increasingly important in traditional CPI operations, as well as in oil/gas exploration and production. This book is the source for predicting electrolyte systems behavior, an indispensable "do–it–yourself" guide, with a blueprint for formulating predictive mathematical electrolyte models, recommended tabular values to use in these models, and annotated bibliographies. The final chapter is a general recipe for formulating complete predictive models for electrolytes, along with a series of worked illustrative examples. It can serve as a useful research and application tool for the practicing process engineer, and as a textbook for the chemical engineering student.
Specificaties
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Inhoudsopgave
I. INTRODUCTION.
<p>II. THERMODYNAMICS OF SOLUTIONS.</p>
<p>Basic Thermodynamic Functions.</p>
<p>Solutions Basic Definitions and Concepts.</p>
<p>Equilibrium Necessary Conditions.</p>
<p>Activities, Activity Coefficients and Standard States.</p>
<p>III. EQUILIBRIUM CONSTANTS.</p>
<p>Ionic and/or Reaction Equilibrium in Aqueous Solutions.</p>
<p>Solubility Equilibria Between Crystals and Saturated Solutions.</p>
<p>Vapor–Liquid Equilibria in Aqueous Solutions.</p>
<p>Temperature Effects on the Equilibrium Constant.</p>
<p>Estimating Temperature Effects on Heat Capacity and Other Thermodynamic Properties.</p>
<p>Equilibrium Constants from Tabulated Data.</p>
<p>Pressure Effects on the Equilibrium Constant.</p>
<p>Appendix 3.1 Criss and Cobble Parameters.</p>
<p>IV. ACTIVITY COEFFICIENTS OF SINGLE STRONG ELECTROLYTES.</p>
<p>History.</p>
<p>Bromley s Method.</p>
<p>Meissner s Method.</p>
<p>Pitzer s Method.</p>
<p>Chen s Method.</p>
<p>Temperature Effects.</p>
<p>Application.</p>
<p>Bromley s Extended Equation.</p>
<p>Comparison of Temperature Effect Methods.</p>
<p>Appendix 4.1 Values for Guggenheim s Parameter.</p>
<p>Table 1: Values for Uni–univalent Electrolytes.</p>
<p>Table 2: and B Values of Bi–univalent and Uni–bivalent Electrolytes from Freezing Points.</p>
<p>Methods for Calculating .</p>
<p>Appendix 4.2 Bromley Interaction Parameters.</p>
<p>Table 1: B Values at 25°C Determined by the Method of Least Squares on Log to I=6.0 (or less of limited data).</p>
<p>Table 2: Individual Ion Values of B and in Aqueous Solutions at 25°C.</p>
<p>Table 3: Bivalent Metal Sulfates at 25°C.</p>
<p>Appendix 4.4 Pitzer Parameters,</p>
<p>Table 1: Inorganic Acids, Bases and Salts of 1–1 Type.</p>
<p>Table 2: Salts of Carboxylic Acids (1–1 Type).</p>
<p>Table 3: Tetraalkylammonium Halides.</p>
<p>Table 4: Sulfonic Acids and Salts (1–1 Type).</p>
<p>Table 5: Additional 1–1 Type Organic Salts.</p>
<p>Table 6: Inorganic Compounds of 2–1 Type.</p>
<p>Table 7: Organic Electrolytes of 2–1 Type.</p>
<p>Table 8: 3–1 Electrolytes.</p>
<p>Table 9: 4–1 Electrolytes.</p>
<p>Table 10: 5–1 Electrolytes.</p>
<p>Table 11: 2–2 Electrolytes.</p>
<p>Appendix 4.5 Pitzer Parameter Derivatives.</p>
<p>Table 1: Temperature Derivatives of Parameters for 1–1 Electrolytes Evaluated from Calorimetric Data.</p>
<p>Table 2: Temperature Derivatives of Parameters for 2–1 and 1–2 Electrolytes Evaluated from Calorimetric Data.</p>
<p>Table 3: Temperature Derivatives of Parameters for 3–1 and 2–2 Electrolytes Evaluated from Calorimetric Parameters.</p>
<p>Appendix 4–6 Chen Parameters.</p>
<p>Table: Values Fit for Molality Mean Ionic Activity Coefficient Data of Aqueous Electrolytes at 298.15 K.</p>
<p>V. ACTIVITY COEFFICIENTS OF MULTICOMPONET STRONG ELECTROLYTES.</p>
<p>Guggenheim s Method for Multicomponent Solutions.</p>
<p>Bromley s Method for Multicomponent Solutions.</p>
<p>Meissner s Method for Multicomponent Solutions.</p>
<p>Pitzer s Method for Multicomponent Solutions.</p>
<p>Application.</p>
<p>Phase Diagram Calculations.</p>
<p>Appendix 5.1 Values for Pitzer s and Parameters.</p>
<p>Table 1: Parameters for mixed electrolytes with viral coefficient equations (at 25°C).</p>
<p>Table 2: Parameters for the viral coefficient equations at 25°C,</p>
<p>Table 3: Parameters for binary mixtures with a common ion at 25°C.</p>
<p>VI. ACTIVITY COEFFICIENT OF STRONGLY COMPLEXING COMPOUNDS.</p>
<p>Identification of Complexing Electrolytes.</p>
<p>Phosphoric Acid.</p>
<p>Sulfuric Acid.</p>
<p>Zinc Chloride.</p>
<p>Ferric Chloride.</p>
<p>Cuprous Chloride.</p>
<p>Calcium Sulfate.</p>
<p>Sodium Sulfate.</p>
<p>Other Chloride Complexes.</p>
<p>Activity Coefficient Methods.</p>
<p>Summary.</p>
<p>Appendix 6.1 Cuprous Chloride.</p>
<p>Table 1a: Interaction Parameters.</p>
<p>Table 1b: Three Parameter Set.</p>
<p>Table 2: Equilibrium Constants and Heats of Reaction.</p>
<p>Table 3a: Equilibrium Constants and Changes in Thermodynamic Properties for Formation of CuC1¯ and CuC1²¯ from CuC1(s) + nC1¯ = CuC1</p>
<p>Table 3b: Equilibrium Constants and Changes in Thermodynamic Properties for Formation of CuC1¯ and CuC1²¯ from Cu<sup>+</sup> + nC1¯ = CuC1<sub>n</sub><sub>(n–1</sub>.</p>
<p>VII. ACTIVITY COEFFICIENTS OF WEAK ELECTROLYTES AND MOLECULAR SPECIES.</p>
<p>Setschénow Equation.</p>
<p>Pitzer Based Equations.</p>
<p>Predictions Based Upon Theoretical Equations.</p>
<p>Appendix 7.1 Salting Out Parameters for Phenol in Aqueous Salt Solutions at 25°C Celsius.</p>
<p>Appendix 7.2 Salting Out Parameters from Pawlikowski and Prausnitz for Nonpolar Gases in Common Salt Solutions at Moderate Temperatures.</p>
<p>Table 1: Lennard Jones Parameters for Nonpolar Gases as Reported by Liabastre (S14).</p>
<p>Table 2: Salting Out Parameters for Strong Electrolytes in Equation (7.18) at 25°C.</p>
<p>Table 3: Temperature Dependence of the Salting Out Parameters for Equation (7.19).</p>
<p>Table 4: Salting Out Parameters for Individual Ions for Equation (7.20).</p>
<p>Table 5: Temperature Dependence of the Salting Out Constants for Individual Loss.</p>
<p>VIII. THERMODYNAMIC FUNCTIONS DERIVED FROM ACTIVITY COEFFICIENTS.</p>
<p>Density.</p>
<p>Enthalpy.</p>
<p>Excess Enthalpy.</p>
<p>Example.</p>
<p>IX. WORKED EXAMPLES.</p>
<p>Model Formulation.</p>
<p>Obtaining Coefficients.</p>
<p>Model Solution.</p>
<p>Specific Examples.</p>
<p>Appendix 9.1 Parameters for Beutier and Renon s Method.</p>
<p>Table 1: Temperature fit parameters for equilibrium constants.</p>
<p>Table 2: Temperature fit parameters for Henry s constants.</p>
<p>Table 3: Pitzer ion–ion interaction parameters.</p>
<p>Table 4: Temperature fit molecule self interaction parameters.</p>
<p>Table 5: Dielectric effect parameters.</p>
<p>Appendix 9.2– Parameters for Edwards, Maurer, Newman and Prausnitz Method.</p>
<p>Table 1: Temperature fit parameters for equilibrium constants.</p>
<p>Table 2: Temperature fit parameters for Henry s constants.</p>
<p>Table 3: Ion–ion interaction parameters.</p>
<p>Table 4: Temperature fit molecule self interaction parameters.</p>
<p>Table 5: Molecule–ion interaction parameters.</p>
<p>Appendix 9.3 – Fugacity Coefficient Calculation.</p>
<p>Table 1: Pure component parameters.</p>
<p>Table 2: Nonpolar and polar contribution to parameters &alpha; and &beta; for four polar gases.</p>
<p>Table 3: Interaction parameter <sup>&alpha;</sup><sub>12</sub> for polar–nonpolar mixtures.</p>
<p>Table 4: Parameter<sup>&alpha;</sup><sub>12</sub> for binary mixtures of nonpolar gases.</p>
<p>Table 5: Interaction parameter <sup>&alpha;</sup><sub>12</sub> for polar–polar mixtures.</p>
<p>Appendix 9.4 – Brelvi and O Connell Correlation for Partial Molar Volumes.</p>
<p>Table 1: Characteristic Volumes.</p>
<p>Appendix 9.5 Gypsum Solubility Study Parameters at 25°C.</p>
<p>Table 1: Binary solution parameters for the Pitzer equations.</p>
<p>Table 2: Mixed electrolyte solution parameters for the Pitzer equations.</p>
<p>Table 3: Gypsum solubility product at 25°C.</p>
<p>Appendix A. Computer Programs for Solving Equilibria Problems.</p>
<p>Appendix B. Selected Thermodynamic Data.</p>
<p>Appendix C. Compiled Thermodynamic Data Sources for Aqueous and Biochemical Systems: An Annotated Bibliography (1930–1983).</p>
<p>Index.</p>
<p>II. THERMODYNAMICS OF SOLUTIONS.</p>
<p>Basic Thermodynamic Functions.</p>
<p>Solutions Basic Definitions and Concepts.</p>
<p>Equilibrium Necessary Conditions.</p>
<p>Activities, Activity Coefficients and Standard States.</p>
<p>III. EQUILIBRIUM CONSTANTS.</p>
<p>Ionic and/or Reaction Equilibrium in Aqueous Solutions.</p>
<p>Solubility Equilibria Between Crystals and Saturated Solutions.</p>
<p>Vapor–Liquid Equilibria in Aqueous Solutions.</p>
<p>Temperature Effects on the Equilibrium Constant.</p>
<p>Estimating Temperature Effects on Heat Capacity and Other Thermodynamic Properties.</p>
<p>Equilibrium Constants from Tabulated Data.</p>
<p>Pressure Effects on the Equilibrium Constant.</p>
<p>Appendix 3.1 Criss and Cobble Parameters.</p>
<p>IV. ACTIVITY COEFFICIENTS OF SINGLE STRONG ELECTROLYTES.</p>
<p>History.</p>
<p>Bromley s Method.</p>
<p>Meissner s Method.</p>
<p>Pitzer s Method.</p>
<p>Chen s Method.</p>
<p>Temperature Effects.</p>
<p>Application.</p>
<p>Bromley s Extended Equation.</p>
<p>Comparison of Temperature Effect Methods.</p>
<p>Appendix 4.1 Values for Guggenheim s Parameter.</p>
<p>Table 1: Values for Uni–univalent Electrolytes.</p>
<p>Table 2: and B Values of Bi–univalent and Uni–bivalent Electrolytes from Freezing Points.</p>
<p>Methods for Calculating .</p>
<p>Appendix 4.2 Bromley Interaction Parameters.</p>
<p>Table 1: B Values at 25°C Determined by the Method of Least Squares on Log to I=6.0 (or less of limited data).</p>
<p>Table 2: Individual Ion Values of B and in Aqueous Solutions at 25°C.</p>
<p>Table 3: Bivalent Metal Sulfates at 25°C.</p>
<p>Appendix 4.4 Pitzer Parameters,</p>
<p>Table 1: Inorganic Acids, Bases and Salts of 1–1 Type.</p>
<p>Table 2: Salts of Carboxylic Acids (1–1 Type).</p>
<p>Table 3: Tetraalkylammonium Halides.</p>
<p>Table 4: Sulfonic Acids and Salts (1–1 Type).</p>
<p>Table 5: Additional 1–1 Type Organic Salts.</p>
<p>Table 6: Inorganic Compounds of 2–1 Type.</p>
<p>Table 7: Organic Electrolytes of 2–1 Type.</p>
<p>Table 8: 3–1 Electrolytes.</p>
<p>Table 9: 4–1 Electrolytes.</p>
<p>Table 10: 5–1 Electrolytes.</p>
<p>Table 11: 2–2 Electrolytes.</p>
<p>Appendix 4.5 Pitzer Parameter Derivatives.</p>
<p>Table 1: Temperature Derivatives of Parameters for 1–1 Electrolytes Evaluated from Calorimetric Data.</p>
<p>Table 2: Temperature Derivatives of Parameters for 2–1 and 1–2 Electrolytes Evaluated from Calorimetric Data.</p>
<p>Table 3: Temperature Derivatives of Parameters for 3–1 and 2–2 Electrolytes Evaluated from Calorimetric Parameters.</p>
<p>Appendix 4–6 Chen Parameters.</p>
<p>Table: Values Fit for Molality Mean Ionic Activity Coefficient Data of Aqueous Electrolytes at 298.15 K.</p>
<p>V. ACTIVITY COEFFICIENTS OF MULTICOMPONET STRONG ELECTROLYTES.</p>
<p>Guggenheim s Method for Multicomponent Solutions.</p>
<p>Bromley s Method for Multicomponent Solutions.</p>
<p>Meissner s Method for Multicomponent Solutions.</p>
<p>Pitzer s Method for Multicomponent Solutions.</p>
<p>Application.</p>
<p>Phase Diagram Calculations.</p>
<p>Appendix 5.1 Values for Pitzer s and Parameters.</p>
<p>Table 1: Parameters for mixed electrolytes with viral coefficient equations (at 25°C).</p>
<p>Table 2: Parameters for the viral coefficient equations at 25°C,</p>
<p>Table 3: Parameters for binary mixtures with a common ion at 25°C.</p>
<p>VI. ACTIVITY COEFFICIENT OF STRONGLY COMPLEXING COMPOUNDS.</p>
<p>Identification of Complexing Electrolytes.</p>
<p>Phosphoric Acid.</p>
<p>Sulfuric Acid.</p>
<p>Zinc Chloride.</p>
<p>Ferric Chloride.</p>
<p>Cuprous Chloride.</p>
<p>Calcium Sulfate.</p>
<p>Sodium Sulfate.</p>
<p>Other Chloride Complexes.</p>
<p>Activity Coefficient Methods.</p>
<p>Summary.</p>
<p>Appendix 6.1 Cuprous Chloride.</p>
<p>Table 1a: Interaction Parameters.</p>
<p>Table 1b: Three Parameter Set.</p>
<p>Table 2: Equilibrium Constants and Heats of Reaction.</p>
<p>Table 3a: Equilibrium Constants and Changes in Thermodynamic Properties for Formation of CuC1¯ and CuC1²¯ from CuC1(s) + nC1¯ = CuC1</p>
<p>Table 3b: Equilibrium Constants and Changes in Thermodynamic Properties for Formation of CuC1¯ and CuC1²¯ from Cu<sup>+</sup> + nC1¯ = CuC1<sub>n</sub><sub>(n–1</sub>.</p>
<p>VII. ACTIVITY COEFFICIENTS OF WEAK ELECTROLYTES AND MOLECULAR SPECIES.</p>
<p>Setschénow Equation.</p>
<p>Pitzer Based Equations.</p>
<p>Predictions Based Upon Theoretical Equations.</p>
<p>Appendix 7.1 Salting Out Parameters for Phenol in Aqueous Salt Solutions at 25°C Celsius.</p>
<p>Appendix 7.2 Salting Out Parameters from Pawlikowski and Prausnitz for Nonpolar Gases in Common Salt Solutions at Moderate Temperatures.</p>
<p>Table 1: Lennard Jones Parameters for Nonpolar Gases as Reported by Liabastre (S14).</p>
<p>Table 2: Salting Out Parameters for Strong Electrolytes in Equation (7.18) at 25°C.</p>
<p>Table 3: Temperature Dependence of the Salting Out Parameters for Equation (7.19).</p>
<p>Table 4: Salting Out Parameters for Individual Ions for Equation (7.20).</p>
<p>Table 5: Temperature Dependence of the Salting Out Constants for Individual Loss.</p>
<p>VIII. THERMODYNAMIC FUNCTIONS DERIVED FROM ACTIVITY COEFFICIENTS.</p>
<p>Density.</p>
<p>Enthalpy.</p>
<p>Excess Enthalpy.</p>
<p>Example.</p>
<p>IX. WORKED EXAMPLES.</p>
<p>Model Formulation.</p>
<p>Obtaining Coefficients.</p>
<p>Model Solution.</p>
<p>Specific Examples.</p>
<p>Appendix 9.1 Parameters for Beutier and Renon s Method.</p>
<p>Table 1: Temperature fit parameters for equilibrium constants.</p>
<p>Table 2: Temperature fit parameters for Henry s constants.</p>
<p>Table 3: Pitzer ion–ion interaction parameters.</p>
<p>Table 4: Temperature fit molecule self interaction parameters.</p>
<p>Table 5: Dielectric effect parameters.</p>
<p>Appendix 9.2– Parameters for Edwards, Maurer, Newman and Prausnitz Method.</p>
<p>Table 1: Temperature fit parameters for equilibrium constants.</p>
<p>Table 2: Temperature fit parameters for Henry s constants.</p>
<p>Table 3: Ion–ion interaction parameters.</p>
<p>Table 4: Temperature fit molecule self interaction parameters.</p>
<p>Table 5: Molecule–ion interaction parameters.</p>
<p>Appendix 9.3 – Fugacity Coefficient Calculation.</p>
<p>Table 1: Pure component parameters.</p>
<p>Table 2: Nonpolar and polar contribution to parameters &alpha; and &beta; for four polar gases.</p>
<p>Table 3: Interaction parameter <sup>&alpha;</sup><sub>12</sub> for polar–nonpolar mixtures.</p>
<p>Table 4: Parameter<sup>&alpha;</sup><sub>12</sub> for binary mixtures of nonpolar gases.</p>
<p>Table 5: Interaction parameter <sup>&alpha;</sup><sub>12</sub> for polar–polar mixtures.</p>
<p>Appendix 9.4 – Brelvi and O Connell Correlation for Partial Molar Volumes.</p>
<p>Table 1: Characteristic Volumes.</p>
<p>Appendix 9.5 Gypsum Solubility Study Parameters at 25°C.</p>
<p>Table 1: Binary solution parameters for the Pitzer equations.</p>
<p>Table 2: Mixed electrolyte solution parameters for the Pitzer equations.</p>
<p>Table 3: Gypsum solubility product at 25°C.</p>
<p>Appendix A. Computer Programs for Solving Equilibria Problems.</p>
<p>Appendix B. Selected Thermodynamic Data.</p>
<p>Appendix C. Compiled Thermodynamic Data Sources for Aqueous and Biochemical Systems: An Annotated Bibliography (1930–1983).</p>
<p>Index.</p>
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