Claudio Olivera-Fuentes, Costas Panayiotou, Grazyna Wilczek-Vera, Juan H. Vera
Classical and Molecular Thermodynamics of Fluid Systems
Principles and Applications
Claudio Olivera-Fuentes, Costas Panayiotou, Grazyna Wilczek-Vera, Juan H. Vera
Classical and Molecular Thermodynamics of Fluid Systems
Principles and Applications
- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
This text explores the connections between different thermodynamic subjects related to fluid systems, from first principles to applied topics. It presents the fundamentals and treatment of mixtures and offers examples and references. The new edition explores advances and contains problems and solutions.
Andere Kunden interessierten sich auch für
- S Mostafa GhiaasiaanConvective Heat and Mass Transfer264,99 €
- Paul J LanasaFluid Flow Measurement82,99 €
- S S DukhinDynamics of Adsorption at Liquid Interfaces60,99 €
- Guy B. Marin (ed.)Advances in Chemical Engineering224,99 €
- Juan J. De PabloMolecular Engineering Thermodynamics97,99 €
- Drying of Complex Fluid Drops212,99 €
- Guido BurestiELEMENTS OF FLUID DYNAMICS67,99 €
-
-
-
This text explores the connections between different thermodynamic subjects related to fluid systems, from first principles to applied topics. It presents the fundamentals and treatment of mixtures and offers examples and references. The new edition explores advances and contains problems and solutions.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 594
- Erscheinungstermin: 24. Oktober 2024
- Englisch
- Abmessung: 254mm x 178mm
- ISBN-13: 9781032557342
- ISBN-10: 1032557346
- Artikelnr.: 70437520
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 594
- Erscheinungstermin: 24. Oktober 2024
- Englisch
- Abmessung: 254mm x 178mm
- ISBN-13: 9781032557342
- ISBN-10: 1032557346
- Artikelnr.: 70437520
Juan H. Vera is Professor Emeritus, Department of Chemical Engineering, McGill University, Montreal, Canada. He earned a doctorate (Ing. Quim.) at the Universidad Tecnica Federico Santa Maria, Chile, and a master of science in chemical engineering at the University of California, Berkley. He coauthored the first edition of this book, a manual on copper metallurgy (in Spanish), a module in Elsevier Encyclopedia, co-edited the book Ionic Surfactants and Aqueous Solutions: Biomolecules, Metals and Nanoparticles (2018), and authored more than 200 refereed publications in international journals. He has an international patent on the extraction of proteins and a Canadian patent on the extraction of heavy metals. Grazyna Wilczek-Vera is a chemist who has taught and conducted research in various areas of thermodynamics at several universities. During her more than 30-year academic career, she served as Faculty Lecturer and Director of Undergraduate Studies in the Department of Chemistry and as Research Associate in the Department of Chemical Engineering at McGill University, Montreal, Canada, and as Adjunct in the Department of Chemistry, University of Warsaw, Poland. She received the 2008 Principal's Prize for Excellence in Teaching at McGill University. She earned a PhD in chemical sciences (with distinction) and a master of science in chemistry (with distinction) at the University of Warsaw. She has authored 60 refereed publications in journals, given 38 conference presentations, and coauthored 3 books. Claudio Olivera-Fuentes is Professor Emeritus in the Thermodynamics and Transport Phenomena Department and Coordinator of Applied Sciences and Engineering in the Dean's Office of Research and Development at Universidad Simón Bolívar, Caracas, Venezuela. He earned a chemical engineering degree at the Universidad Técnica Federico Santa María, Chile, and an MSc in chemical engineering at the University of Manchester Institute of Science and Technology, UK. He has been an Invited Researcher at the University of Concepción, Chile, and a Visiting Scholar at the University of Pennsylvania. He has authored over 120 publications in conference proceedings and scientific journals, three book chapters, and one textbook on vector and tensor analysis applied to transport phenomena. Among other recognitions, he received the 2003 Procter & Gamble of Venezuela Award for Excellence in Teaching and the 2016 Simón Rodríguez Award for Lifetime Academic Achievement. Costas Panayiotou is Professor Emeritus, Department of Chemical Engineering, Aristotle University of Thessaloniki, Greece. He earned a PhD at McGill University, Montreal, Canada. He was a Visiting Professor at the University of Texas, Austin, and at Ecole Polytechnique Federale, Lausanne, Switzerland, and he was Otto Monsted Professor at the Technical University of Denmark (DTU). He has published more than 250 peer-reviewed articles in international journals, ten book chapters, and two textbooks, and he has served on the editorial boards of ACS and Elsevier journals.
Section I: Fundamentals. 1. Basic Concepts and Definitions. 2. The First
and Second Laws of Thermodynamics. 3. Conservation of Energy in an Open
Flow System: Definition of Enthalpy. 4. The Algebra of State Functions: The
Helmholtz and Gibbs Functions. 5. Calculation of Changes in the Value of
Thermodynamic Properties. Section II: Mixtures. 6. Partial Molar Properties
and Property Changes by Mixing. 7. The Chemical Potential and the
Gibbs-Helmholtz Equation. 8. The Principles of Physical and Chemical
Equilibrium. 9. The Phase Rule and Duhem Theorem. 10. Generality of the
Thermodynamic Treatment. 11. The Ideal Gas and Ideal Gas Mixtures. 12. The
Use of Fugacity and Activity in Equilibrium Studies. 13. Calculation of
Fugacities from Equations of State (EOS). 14. Fugacity of a Mixture and of
Its Components. 15. Fugacities and Activities in Liquid Mixtures of Non
Electrolytes. 16. Activity Coefficients and Excess Properties. 17. Mixture
Behavior, Stability and Azeotropy. 18. The Thermodynamics of Aqueous
Electrolyte Solutions. 19. The Thermodynamics of Polymer Solutions.
Section III: Applications. 20. Applications of Polymer Solution
Thermodynamics. 21. The Thermodynamics of Chemical Reactions. 22. The
Thermodynamics of Equilibrium Based Separation Processes. 23. Heat Effects.
24. Adsorption of Gases on Solids. Section IV: Special Topics. 25. The
Thermodynamics of Flow of Compressible Fluids. 26. Elements of Statistical
Thermodynamics. 27. Statistical Thermodynamics Basis of Equations of State.
28. Statistical Thermodynamics Basis of Excess Gibbs Functions. 29.
Statistical Thermodynamics Approach to the Generalized van der Waals
Theory. 30. Generalized Lattice-Fluid Model. 31. Cosmo-RS-Type Models. 32.
Thermodynamics of Hydrogen Bonding. 33. SAFT. 34. The Activity Coefficients
of Individual Ions - Past, Present and Future. Section V: Appendices.
Appendix A. Material Balances in Open Flow Systems. Appendix B. Working
with the Virial EOS. Appendix C. Working with the PRSV EOS. Appendix D.
Working with ASOG-KT.
and Second Laws of Thermodynamics. 3. Conservation of Energy in an Open
Flow System: Definition of Enthalpy. 4. The Algebra of State Functions: The
Helmholtz and Gibbs Functions. 5. Calculation of Changes in the Value of
Thermodynamic Properties. Section II: Mixtures. 6. Partial Molar Properties
and Property Changes by Mixing. 7. The Chemical Potential and the
Gibbs-Helmholtz Equation. 8. The Principles of Physical and Chemical
Equilibrium. 9. The Phase Rule and Duhem Theorem. 10. Generality of the
Thermodynamic Treatment. 11. The Ideal Gas and Ideal Gas Mixtures. 12. The
Use of Fugacity and Activity in Equilibrium Studies. 13. Calculation of
Fugacities from Equations of State (EOS). 14. Fugacity of a Mixture and of
Its Components. 15. Fugacities and Activities in Liquid Mixtures of Non
Electrolytes. 16. Activity Coefficients and Excess Properties. 17. Mixture
Behavior, Stability and Azeotropy. 18. The Thermodynamics of Aqueous
Electrolyte Solutions. 19. The Thermodynamics of Polymer Solutions.
Section III: Applications. 20. Applications of Polymer Solution
Thermodynamics. 21. The Thermodynamics of Chemical Reactions. 22. The
Thermodynamics of Equilibrium Based Separation Processes. 23. Heat Effects.
24. Adsorption of Gases on Solids. Section IV: Special Topics. 25. The
Thermodynamics of Flow of Compressible Fluids. 26. Elements of Statistical
Thermodynamics. 27. Statistical Thermodynamics Basis of Equations of State.
28. Statistical Thermodynamics Basis of Excess Gibbs Functions. 29.
Statistical Thermodynamics Approach to the Generalized van der Waals
Theory. 30. Generalized Lattice-Fluid Model. 31. Cosmo-RS-Type Models. 32.
Thermodynamics of Hydrogen Bonding. 33. SAFT. 34. The Activity Coefficients
of Individual Ions - Past, Present and Future. Section V: Appendices.
Appendix A. Material Balances in Open Flow Systems. Appendix B. Working
with the Virial EOS. Appendix C. Working with the PRSV EOS. Appendix D.
Working with ASOG-KT.
Section I: Fundamentals. 1. Basic Concepts and Definitions. 2. The First
and Second Laws of Thermodynamics. 3. Conservation of Energy in an Open
Flow System: Definition of Enthalpy. 4. The Algebra of State Functions: The
Helmholtz and Gibbs Functions. 5. Calculation of Changes in the Value of
Thermodynamic Properties. Section II: Mixtures. 6. Partial Molar Properties
and Property Changes by Mixing. 7. The Chemical Potential and the
Gibbs-Helmholtz Equation. 8. The Principles of Physical and Chemical
Equilibrium. 9. The Phase Rule and Duhem Theorem. 10. Generality of the
Thermodynamic Treatment. 11. The Ideal Gas and Ideal Gas Mixtures. 12. The
Use of Fugacity and Activity in Equilibrium Studies. 13. Calculation of
Fugacities from Equations of State (EOS). 14. Fugacity of a Mixture and of
Its Components. 15. Fugacities and Activities in Liquid Mixtures of Non
Electrolytes. 16. Activity Coefficients and Excess Properties. 17. Mixture
Behavior, Stability and Azeotropy. 18. The Thermodynamics of Aqueous
Electrolyte Solutions. 19. The Thermodynamics of Polymer Solutions.
Section III: Applications. 20. Applications of Polymer Solution
Thermodynamics. 21. The Thermodynamics of Chemical Reactions. 22. The
Thermodynamics of Equilibrium Based Separation Processes. 23. Heat Effects.
24. Adsorption of Gases on Solids. Section IV: Special Topics. 25. The
Thermodynamics of Flow of Compressible Fluids. 26. Elements of Statistical
Thermodynamics. 27. Statistical Thermodynamics Basis of Equations of State.
28. Statistical Thermodynamics Basis of Excess Gibbs Functions. 29.
Statistical Thermodynamics Approach to the Generalized van der Waals
Theory. 30. Generalized Lattice-Fluid Model. 31. Cosmo-RS-Type Models. 32.
Thermodynamics of Hydrogen Bonding. 33. SAFT. 34. The Activity Coefficients
of Individual Ions - Past, Present and Future. Section V: Appendices.
Appendix A. Material Balances in Open Flow Systems. Appendix B. Working
with the Virial EOS. Appendix C. Working with the PRSV EOS. Appendix D.
Working with ASOG-KT.
and Second Laws of Thermodynamics. 3. Conservation of Energy in an Open
Flow System: Definition of Enthalpy. 4. The Algebra of State Functions: The
Helmholtz and Gibbs Functions. 5. Calculation of Changes in the Value of
Thermodynamic Properties. Section II: Mixtures. 6. Partial Molar Properties
and Property Changes by Mixing. 7. The Chemical Potential and the
Gibbs-Helmholtz Equation. 8. The Principles of Physical and Chemical
Equilibrium. 9. The Phase Rule and Duhem Theorem. 10. Generality of the
Thermodynamic Treatment. 11. The Ideal Gas and Ideal Gas Mixtures. 12. The
Use of Fugacity and Activity in Equilibrium Studies. 13. Calculation of
Fugacities from Equations of State (EOS). 14. Fugacity of a Mixture and of
Its Components. 15. Fugacities and Activities in Liquid Mixtures of Non
Electrolytes. 16. Activity Coefficients and Excess Properties. 17. Mixture
Behavior, Stability and Azeotropy. 18. The Thermodynamics of Aqueous
Electrolyte Solutions. 19. The Thermodynamics of Polymer Solutions.
Section III: Applications. 20. Applications of Polymer Solution
Thermodynamics. 21. The Thermodynamics of Chemical Reactions. 22. The
Thermodynamics of Equilibrium Based Separation Processes. 23. Heat Effects.
24. Adsorption of Gases on Solids. Section IV: Special Topics. 25. The
Thermodynamics of Flow of Compressible Fluids. 26. Elements of Statistical
Thermodynamics. 27. Statistical Thermodynamics Basis of Equations of State.
28. Statistical Thermodynamics Basis of Excess Gibbs Functions. 29.
Statistical Thermodynamics Approach to the Generalized van der Waals
Theory. 30. Generalized Lattice-Fluid Model. 31. Cosmo-RS-Type Models. 32.
Thermodynamics of Hydrogen Bonding. 33. SAFT. 34. The Activity Coefficients
of Individual Ions - Past, Present and Future. Section V: Appendices.
Appendix A. Material Balances in Open Flow Systems. Appendix B. Working
with the Virial EOS. Appendix C. Working with the PRSV EOS. Appendix D.
Working with ASOG-KT.