Record:   Prev Next
Author Glasgow, Larry A
Title Transport Phenomena : An Introduction to Advanced Topics
Imprint Hoboken : John Wiley & Sons, Incorporated, 2010
©2010
book jacket
Edition 1st ed
Descript 1 online resource (281 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Note TRANSPORT PHENOMENA: An Introduction to Advanced Topics -- CONTENTS -- PREFACE -- 1 INTRODUCTION AND SOME USEFUL REVIEW -- 1.1 A MESSAGE FOR THE STUDENT -- 1.2 DIFFERENTIAL EQUATIONS -- 1.3 CLASSIFICATION OF PARTIAL DIFFERENTIAL EQUATIONS AND BOUNDARY CONDITIONS -- 1.4 NUMERICAL SOLUTIONS FOR PARTIAL DIFFERENTIAL EQUATIONS -- 1.5 VECTORS, TENSORS, AND THE EQUATION OF MOTION -- 1.6 THE MEN FOR WHOM THE NAVIER-STOKES EQUATIONS ARE NAMED -- 1.7 SIR ISAAC NEWTON -- REFERENCES -- 2 INVISCID FLOW: SIMPLIFIED FLUID MOTION -- 2.1 INTRODUCTION -- 2.2 TWO-DIMENSIONAL POTENTIAL FLOW -- 2.3 NUMERICAL SOLUTION OF POTENTIAL FLOW PROBLEMS -- 2.4 CONCLUSION -- REFERENCES -- 3 LAMINAR FLOWS IN DUCTS AND ENCLOSURES -- 3.1 INTRODUCTION -- 3.2 HAGEN-POISEUILLE FLOW -- 3.3 TRANSIENT HAGEN-POISEUILLE FLOW -- 3.4 POISEUILLE FLOW IN AN ANNULUS -- 3.5 DUCTS WITH OTHER CROSS SECTIONS -- 3.6 COMBINED COUETTE AND POISEUILLE FLOWS -- 3.7 COUETTE FLOWS IN ENCLOSURES -- 3.8 GENERALIZED TWO-DIMENSIONAL FLUID MOTION IN DUCTS -- 3.9 SOME CONCERNS IN COMPUTATIONAL FLUID MECHANICS -- 3.10 FLOW IN THE ENTRANCE OF DUCTS -- 3.11 CREEPING FLUID MOTIONS IN DUCTS AND CAVITIES -- 3.12 MICROFLUIDICS: FLOW IN VERY SMALL CHANNELS -- 3.12.1 Electrokinetic Phenomena -- 3.12.2 Gases in Microfluidics -- 3.13 FLOWS IN OPEN CHANNELS -- 3.14 PULSATILE FLOWS IN CYLINDRICAL DUCTS -- 3.15 SOME CONCLUDING REMARKS FOR INCOMPRESSIBLE VISCOUS FLOWS -- REFERENCES -- 4 EXTERNAL LAMINAR FLOWS AND BOUNDARY-LAYER THEORY -- 4.1 INTRODUCTION -- 4.2 THE FLAT PLATE -- 4.3 FLOW SEPARATION PHENOMENA ABOUT BLUFF BODIES -- 4.4 BOUNDARY LAYER ON A WEDGE: THE FALKNER-SKAN PROBLEM -- 4.5 THE FREE JET -- 4.6 INTEGRAL MOMENTUM EQUATIONS -- 4.7 HIEMENZ STAGNATION FLOW -- 4.8 FLOW IN THE WAKE OF A FLAT PLATE AT ZERO INCIDENCE -- 4.9 CONCLUSION -- REFERENCES -- 5 INSTABILITY, TRANSITION, AND TURBULENCE -- 5.1 INTRODUCTION
5.2 LINEARIZED HYDRODYNAMIC STABILITY THEORY -- 5.3 INVISCID STABILITY: THE RAYLEIGH EQUATION -- 5.4 STABILITY OF FLOW BETWEEN CONCENTRIC CYLINDERS -- 5.5 TRANSITION -- 5.5.1 Transition in Hagen-Poiseuille Flow -- 5.5.2 Transition for the Blasius Case -- 5.6 TURBULENCE -- 5.7 HIGHER ORDER CLOSURE SCHEMES -- 5.7.1 Variations -- 5.8 INTRODUCTION TO THE STATISTICAL THEORY OF TURBULENCE -- 5.9 CONCLUSION -- REFERENCES -- 6 HEAT TRANSFER BY CONDUCTION -- 6.1 INTRODUCTION -- 6.2 STEADY-STATE CONDUCTION PROBLEMS IN RECTANGULAR COORDINATES -- 6.3 TRANSIENT CONDUCTION PROBLEMS IN RECTANGULAR COORDINATES -- 6.4 STEADY-STATE CONDUCTION PROBLEMS IN CYLINDRICAL COORDINATES -- 6.5 TRANSIENT CONDUCTION PROBLEMS IN CYLINDRICAL COORDINATES -- 6.6 STEADY-STATE CONDUCTION PROBLEMS IN SPHERICAL COORDINATES -- 6.7 TRANSIENT CONDUCTION PROBLEMS IN SPHERICAL COORDINATES -- 6.8 KELVIN'S ESTIMATE OF THE AGE OF THE EARTH -- 6.9 SOME SPECIALIZED TOPICS IN CONDUCTION -- 6.9.1 Conduction in Extended Surface Heat Transfer -- 6.9.2 Anisotropic Materials -- 6.9.3 Composite Spheres -- 6.10 CONCLUSION -- REFERENCES -- 7 HEAT TRANSFER WITH LAMINAR FLUID MOTION -- 7.1 INTRODUCTION -- 7.2 PROBLEMS IN RECTANGULAR COORDINATES -- 7.2.1 Couette Flow with Thermal Energy Production -- 7.2.2 Viscous Heating with Temperature-Dependent Viscosity -- 7.2.3 The Thermal Entrance Region in Rectangular Coordinates -- 7.2.4 Heat Transfer to Fluid Moving Past a Flat Plate -- 7.3 PROBLEMS IN CYLINDRICAL COORDINATES -- 7.3.1 Thermal Entrance Length in a Tube: The Graetz Problem -- 7.4 NATURAL CONVECTION: BUOYANCY-INDUCED FLUID MOTION -- 7.4.1 Vertical Heated Plate: The Pohlhausen Problem -- 7.4.2 The Heated Horizontal Cylinder -- 7.4.3 Natural Convection in Enclosures -- 7.4.4 Two-Dimensional Rayleigh-Benard Problem -- 7.5 CONCLUSION -- REFERENCES -- 8 DIFFUSIONAL MASS TRANSFER -- 8.1 INTRODUCTION
8.1.1 Diffusivities in Gases -- 8.1.2 Diffusivities in Liquids -- 8.2 UNSTEADY EVAPORATION OF VOLATILE LIQUIDS: THE ARNOLD PROBLEM -- 8.3 DIFFUSION IN RECTANGULAR GEOMETRIES -- 8.3.1 Diffusion into Quiescent Liquids: Absorption -- 8.3.2 Absorption with Chemical Reaction -- 8.3.3 Concentration-Dependent Diffusivity -- 8.3.4 Diffusion Through a Membrane -- 8.3.5 Diffusion Through a Membrane with Variable D -- 8.4 DIFFUSION IN CYLINDRICAL SYSTEMS -- 8.4.1 The Porous Cylinder in Solution -- 8.4.2 The Isothermal Cylindrical Catalyst Pellet -- 8.4.3 Diffusion in Squat (Small L/d) Cylinders -- 8.4.4 Diffusion Through a Membrane with Edge Effects -- 8.4.5 Diffusion with Autocatalytic Reaction in a Cylinder -- 8.5 DIFFUSION IN SPHERICAL SYSTEMS -- 8.5.1 The Spherical Catalyst Pellet with Exothermic Reaction -- 8.5.2 Sorption into a Sphere from a Solution of Limited Volume -- 8.6 SOME SPECIALIZED TOPICS IN DIFFUSION -- 8.6.1 Diffusion with Moving Boundaries -- 8.6.2 Diffusion with Impermeable Obstructions -- 8.6.3 Diffusion in Biological Systems -- 8.6.4 Controlled Release -- 8.7 CONCLUSION -- REFERENCES -- 9 MASS TRANSFER IN WELL-CHARACTERIZED FLOWS -- 9.1 INTRODUCTION -- 9.2 CONVECTIVE MASS TRANSFER IN RECTANGULAR COORDINATES -- 9.2.1 Thin Film on a Vertical Wall -- 9.2.2 Convective Transport with Reaction at the Wall -- 9.2.3 Mass Transfer Between a Flowing Fluid and a Flat Plate -- 9.3 MASS TRANSFER WITH LAMINAR FLOW IN CYLINDRICAL SYSTEMS -- 9.3.1 Fully Developed Flow in a Tube -- 9.3.2 Variations for Mass Transfer in a Cylindrical Tube -- 9.3.3 Mass Transfer in an Annulus with Laminar Flow -- 9.3.4 Homogeneous Reaction in Fully Developed Laminar Flow -- 9.4 MASS TRANSFER BETWEEN A SPHERE AND A MOVING FLUID -- 9.5 SOME SPECIALIZED TOPICS IN CONVECTIVE MASS TRANSFER -- 9.5.1 Using Oscillatory Flows to Enhance Interphase Transport
9.5.2 Chemical Vapor Deposition in Horizontal Reactors -- 9.5.3 Dispersion Effects in Chemical Reactors -- 9.5.4 Transient Operation of a Tubular Reactor -- 9.6 CONCLUSION -- REFERENCES -- 10 HEAT AND MASS TRANSFER IN TURBULENCE -- 10.1 INTRODUCTION -- 10.2 SOLUTION THROUGH ANALOGY -- 10.3 ELEMENTARY CLOSURE PROCESSES -- 10.4 SCALAR TRANSPORT WITH TWO-EQUATION MODELS OF TURBULENCE -- 10.5 TURBULENT FLOWS WITH CHEMICAL REACTIONS -- 10.5.1 Simple Closure Schemes -- 10.6 AN INTRODUCTION TO pdf MODELING -- 10.6.1 The Fokker-Planck Equation and pdf Modeling of Turbulent Reactive Flows -- 10.6.2 Transported pdf Modeling -- 10.7 THE LAGRANGIAN VIEW OF TURBULENT TRANSPORT -- 10.8 CONCLUSIONS -- REFERENCES -- 11 TOPICS IN MULTIPHASE AND MULTICOMPONENT SYSTEMS -- 11.1 GAS-LIQUID SYSTEMS -- 11.1.1 Gas Bubbles in Liquids -- 11.1.2 Bubble Formation at Orifices -- 11.1.3 Bubble Oscillations and Mass Transfer -- 11.2 LIQUID-LIQUID SYSTEMS -- 11.2.1 Droplet Breakage -- 11.3 PARTICLE FLUID SYSTEMS -- 11.3.1 Introduction to Coagulation -- 11.3.2 Collision Mechanisms -- 11.3.3 Self-Preserving Size Distributions -- 11.3.4 Dynamic Behavior of the Particle Size Distribution -- 11.3.5 Other Aspects of Particle Size Distribution Modeling -- 11.3.6 A Highly Simplified Example -- 11.4 MULTICOMPONENT DIFFUSION IN GASES -- 11.4.1 The Stefan-Maxwell Equations -- 11.5 CONCLUSION -- REFERENCES -- PROBLEMS TO ACCOMPANY TRANSPORT PHENOMENA: AN INTRODUCTION TO ADVANCED TOPICS -- APPENDIX A FINITE DIFFERENCE APPROXIMATIONS FOR DERIVATIVES -- APPENDIX B ADDITIONAL NOTES ON BESSEL'S EQUATION AND BESSEL FUNCTIONS -- APPENDIX C SOLVING LAPLACE AND POISSON (ELLIPTIC) PARTIAL DIFFERENTIAL EQUATIONS -- APPENDIX D SOLVING ELEMENTARY PARABOLIC PARTIAL DIFFERENTIAL EQUATIONS -- APPENDIX E ERROR FUNCTION -- APPENDIX F GAMMA FUNCTION -- APPENDIX G REGULAR PERTURBATION
APPENDIX H SOLUTION OF DIFFERENTIAL EQUATIONS BY COLLOCATION -- INDEX
Enables readers to apply transport phenomena principles to solve advanced problems in all areas of engineering and science This book helps readers elevate their understanding of, and their ability to apply, transport phenomena by introducing a broad range of advanced topics as well as analytical and numerical solution techniques. Readers gain the ability to solve complex problems generally not addressed in undergraduate-level courses, including nonlinear, multidimensional transport, and transient molecular and convective transport scenarios. Avoiding rote memorization, the author emphasizes a dual approach to learning in which physical understanding and problem-solving capability are developed simultaneously. Moreover, the author builds both readers' interest and knowledge by: Demonstrating that transport phenomena are pervasive, affecting every aspect of life Offering historical perspectives to enhance readers' understanding of current theory and methods Providing numerous examples drawn from a broad range of fields in the physical and life sciences and engineering Contextualizing problems in scenarios so that their rationale and significance are clear This text generally avoids the use of commercial software for problem solutions, helping readers cultivate a deeper understanding of how solutions are developed. References throughout the text promote further study and encourage the student to contemplate additional topics in transport phenomena. Transport Phenomena is written for advanced undergraduates and graduate students in chemical and mechanical engineering. Upon mastering the principles and techniques presented in this text, all readers will be better able to critically evaluate a broad range of physical phenomena, processes, and systems across many disciplines
Description based on publisher supplied metadata and other sources
Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2020. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries
Link Print version: Glasgow, Larry A. Transport Phenomena : An Introduction to Advanced Topics Hoboken : John Wiley & Sons, Incorporated,c2010 9780470381748
Subject Transport theory -- Mathematics.;Energy transfer.;Electronic books
Electronic books
Record:   Prev Next