Transport Modeling for Environmental Engineers and Scientists - Second Editio

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Informationen zum Autor Mark M. Clark, PhD, was Professor of Civil and Environmental Engineering at the University of Illinois for over twenty years, and is currently Clinical Professor of Civil and Environmental Engineering at Northwestern University, Evanston, Illinois. Klappentext THE REVISED AND UPDATED EDITION OF THE ESSENTIAL TEXT ON TRANSPORT MODELINGTransport Modeling for Environmental Engineers and Scientists, Second Edition addresses the full range of processes that influence how pollutants move through environmental and chemical separations media. Revised and updated for this new Second Edition, the text offers students, teachers, and professionals an unparalleled resource on this important subject.This Second Edition:* Covers the fundamentals of mass and momentum transport processes with an emphasis on aerosol, colloidal, macromolecular, biological, and nanoscale systems* Presents an environmental focus on sedimentation, coagulation, partitioning, adsorption, fluid mechanics, diffusion, dispersion, chromatography, osmosis/reverse osmosis, filtration, and porous media transport* Includes chapters on chemical kinetics and reactor design* Features numerous worked examples and exercises at the end of each chapterThe text's comprehensive approach builds on integrated transport courses in chemical engineering curricula, demonstrating the underlying unity of mass and momentum transport processes, and describing how these underlie pollutant transport, analysis, and control. A key text for understanding the field today, Transport Modeling for Environmental Engineers and Scientists, Second Edition is an essential companion for environmental engineers, civil engineers, chemical engineers, and students and professors in these areas. Zusammenfassung Extensively updated to include advances in the field, this classic guide unites principles of transport phenomena with environmental processes. It covers the fundamentals of mass and momentum transport processes, emphasizing aerosol and colloidal systems. Inhaltsverzeichnis Preface. Acknowledgments. List of Symbols. 1 Conservation Laws and Continua. 1.1. Introduction. 1.2. Conservation Laws: Systems Approach. 1.3. Conservation Laws: Control Volume Approach. 1.4. Conservation Laws: Differential Element Approach. 1.5. Continua. 1.6. Sources, Sinks, Reactions, and Box Models. 1.7. Summary. Exercises. References. Bibliography. 2 Low-Concentration Particle Suspensions and Flows. 2.1. Introduction. 2.2. Drag on a Sphere. 2.3. Drag Force on Nonspherical Particles. 2.4. Low Reynolds Number Particle Dynamics and Stokes' Law. 2.5. Particle Motions in Electric Fields. 2.6. Quiescent and Perfect-Mix Batch Sedimentation. 2.7. Continuous Sedimentation Processes. 2.8. Inertial Forces on Particles and Stopping Distance. 2.9. Inertial Forces in Particle Flows. 2.10. Rotating Flows. 2.11. Centrifugation. 2.12. Summary. Exercises. References. Bibliography. 3 Interactions of Small Charged Particles. 3.1. Introduction. 3.2. Importance of Surface. 3.3. Acquisition of Surface Charge. 3.4. Particle Size, Shape, and Polydispersity. 3.5. The Double Layer and Colloidal Stability. 3.6. The Schulze-Hardy Rule. 3.7. Electrophoresis and Zeta Potential. 3.8. Particle Collision and Fast Coagulation. 3.9. Slow Coagulation. 3.10. Summary. Exercises. References. Bibliography. 4 Adsorption, Partitioning, and Interfaces. 4.1. Introduction. 4.2. Accumulation of Solutes at Interfaces. 4.3. Adsorption at Solid-Liquid and Solid-Gas Interfaces. 4.4. Adsorption Isotherms. 4.5. Linear Equilibrium Partitioning B...