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9780471410775

Transport Phenomena, 2nd Edition

by ; ;
  • ISBN13:

    9780471410775

  • ISBN10:

    0471410772

  • Edition: 2nd
  • Format: Hardcover
  • Copyright: 2001-08-01
  • Publisher: Wiley
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Summary

"Transport Phenomena" has been revised to include deeper and more extensive coverage of heat transfer, enlarged discussion of dimensional analysis, a new chapter on flow of polymers, systematic discussions of convective momentum, and energy. Topics also include mass transport, momentum transport and energy transport, which are presented at three different scales: molecular, microscopic and macroscopic. If this is your first look at Transport Phenomena you'll quickly learn that its balanced introduction to the subject of transport phenomena is the foundation of its long-standing success.

Table of Contents

Preface
The Subject of Transport Phenomena
1(10)
Part 1 Momentum Transport
Viscosity and the Mechanisms of Momentum Transport
11(29)
Newton's Law of Viscosity (Molecular Momentum Transport)
11(5)
Calculation of Momentum Flux
15(1)
Generalization of Newton's Law of Viscosity
16(5)
Pressure and Temperature Dependence of Viscosity
21(2)
Estimation of Viscosity from Critical Properties
23(1)
Molecular Theory of the Viscosity of Gases at Low Density
23(6)
Computation of the Viscosity of Gas Mixture at Low Density
28(1)
Prediction of the Viscosity of a Gas Mixture at Low Density
28(1)
Molecular Theory of the Viscosity of Liquids
29(2)
Estimation of the Viscosity of a Pure Liquid
31(1)
Viscosity of Suspensions and Emulsions
31(3)
Convective Momentum Transport
34(6)
Questions for Discussion
37(1)
Problems
37(3)
Shell Momentum Balances and Velocity Distributions in Laminar Flow
40(35)
Shell Momentum Balances and Boundary Conditions
41(1)
Flow of a Falling Film
42(6)
Calculation of Film Velocity
47(1)
Falling Film with Variable Viscosity
47(1)
Flow Through a Circular Tube
48(5)
Determination of Viscosity from Capillary Flow Data
52(1)
Compressible Flow in a Horizontal Circular Tube
53(1)
Flow Through an Annulus
53(3)
Flow of Two Adjacent Immiscible Fluids
56(2)
Creeping Flow around a Sphere
58(17)
Determination of Viscosity from the Terminal Velocity of a Falling Sphere
61(1)
Questions for Discussion
61(1)
Problems
62(13)
The Equations of Change for Isothermal Systems
75(39)
The Equation of Continuity
77(1)
Normal Stresses at Solid Surfaces for Incompressible Newtonian Fluids
78(1)
The Equation of Motion
78(3)
The Equation of Mechanical Energy
81(1)
The Equation of Angular Momentum
82(1)
The Equation of Change in Terms of the Substantial Derivative
83(3)
The Bernoulli Equation for the Steady Flow of Inviscid Fluids
86(1)
Use of the Equations of Change to Solve Flow Problems
86(11)
Steady Flow in a Long Circular Tube
88(1)
Falling Film with Variable Viscosity
89(1)
Operation of a Couette Viscometer
89(4)
Shape of the Surface of a Rotating Liquid
93(2)
Flow near a Slowly Rotating Sphere
95(2)
Dimensional Analysis of the Equations of Change
97(17)
Transverse Flow around a Circular Cylinder
98(3)
Steady Flow in an Agitated Tank
101(2)
Pressure Drop for Creeping Flow in a Packed Tube
103(1)
Questions for Discussion
104(1)
Problems
104(10)
Velocity Distributions with More than One Independent Variable
114(38)
Time-Dependent Flow of Newtonian Fluids
114(7)
Flow near a Wall Suddenly Set in Motion
115(2)
Unsteady Laminar Flow between Two Parallel Plates
117(3)
Unsteady Laminar Flow near an Oscillating Plate
120(1)
Solving Flow Problems Using a Stream Function
121(5)
Creeping Flow around a Sphere
122(4)
Flow of Inviscid Fluids by Use of the Velocity Potential
126(7)
Potential Flow around a Cylinder
128(2)
Flow into a Rectangular Channel
130(1)
Flow near a Corner
131(2)
Flow near Solid Surfaces by Boundary-Layer Theory
133(19)
Laminar Flow along a Flat Plate (Approximate Solution)
136(1)
Laminar Flow along a Flat Plate (Exact Solution)
137(2)
Flow near a Corner
139(1)
Questions for Discussion
140(1)
Problems
141(11)
Velocity Distributions in Turbulent Flow
152(25)
Comparisons of Laminar and Turbulent Flows
154(2)
Time-Smoothed Equations of Change for Incompressible Fluids
156(3)
The Time-Smoothed Velocity Profile near a Wall
159(3)
Empirical Expressions for the Turbulent Momentum Flux
162(3)
Development of the Reynolds Stress Expression in the Vicinity of the Wall
164(1)
Turbulent Flow in Ducts
165(3)
Estimation of the Average Velocity in a Circular Tube
166(1)
Application of Prandtl's Mixing Length Formula to Turbulent Flow in a Circular Tube
167(1)
Relative Magnitude of Viscosity and Eddy Viscosity
167(1)
Turbulent Flow in Jets
168(9)
Time-Smoothed Velocity Distribution in a Circular Wall Jet
168(4)
Questions for Discussion
172(1)
Problems
172(5)
Interphase Transport in Isothermal Systems
177(20)
Definition of Friction Factors
178(1)
Friction Factors for Flow in Tubes
179(6)
Pressure Drop Required for a Given Flow Rate
183(1)
Flow Rate for a Given Pressure Drop
183(2)
Friction Factors for Flow around Spheres
185(3)
Determination of the Diameter of a Falling Sphere
187(1)
Friction Factors for Packed Columns
188(9)
Questions for Discussion
192(1)
Problems
193(4)
Macroscopic Balances for Isothermal Flow Systems
197(34)
The Macroscopic Mass Balance
198(2)
Draining of a Spherical Tank
199(1)
The Macroscopic Momentum Balance
200(2)
Force Exerted by a Jet (Part a)
201(1)
The Macroscopic Angular Momentum Balance
202(1)
Torque on a Mixing Vessel
202(1)
The Macroscopic Mechanical Energy Balance
203(2)
Force Exerted by a Jet (Part b)
205(1)
Estimation of the Viscous Loss
205(4)
Power Requirement for Pipeline Flow
207(2)
Use of the Macroscopic Balances for Steady-State Problems
209(7)
Pressure Rise and Friction Loss in a Sudden Enlargement
209(1)
Performance of a Liquid-Liquid Ejector
210(2)
Thrust on a Pipe Bend
212(2)
The Impinging Jet
214(1)
Isothermal Flow of a Liquid through an Orifice
215(1)
Use of the Macroscopic Balances for Unsteady-State Problems
216(5)
Acceleration Effects in Unsteady Flow from a Cylindrical Tank
217(2)
Manometer Oscillations
219(2)
Derivation of the Macroscopic Mechanical Energy Balance
221(10)
Questions for Discussion
223(1)
Problems
224(7)
Polymeric Liquids
231(32)
Examples of the Behavior of Polymeric Liquids
232(4)
Rheometry and Material Functions
236(4)
Non-Newtonian Viscosity and the Generalized Newtonian Models
240(4)
Laminar Flow of an Incompressible Power-Law Fluid in a Circular Tube
242(1)
Flow of a Power-Law Fluid in a Narrow Slit
243(1)
Tangential Annular Flow of a Power-Law Fluid
244(1)
Elasticity and the Linear Viscoelastic Models
244(5)
Small-Amplitude Oscillatory Motion
247(1)
Unsteady Viscoelastic Flow near an Oscillating Plate
248(1)
The Corotational Derivatives and the Nonlinear Viscoelastic Models
249(4)
Material Functions for the Oldroyd 6-Constant Model
251(2)
Molecular Theories for Polymeric Liquids
253(10)
Material Functions for the FENE-P Model
255(3)
Questions for Discussion
258(1)
Problems
258(5)
Part II Energy Transport
Thermal Conductivity and the Mechanisms of Energy Transport
263(27)
Fourier's Law of Heat Conduction (Molecular Energy Transport)
266(6)
Measurement of Thermal Conductivity
270(2)
Temperature and Pressure Dependence of Thermal Conductivity
272(2)
Effect of Pressure on Thermal Conductivity
273(1)
Theory of Thermal Conductivity of Gases at Low Density
274(5)
Computation of the Thermal Conductivity of a Monatomic Gas at Low Density
277(1)
Estimation of the Thermal Conductivity of a Polyatomic Gas at Low Density
278(1)
Prediction of the Thermal Conductivity of a Gas Mixture at Low Density
278(1)
Theory of Thermal Conductivity of Liquids
279(1)
Prediction of the Thermal Conductivity of a Liquid
280(1)
Thermal Conductivity of Solids
280(1)
Effective Thermal Conductivity of Composite Solids
281(2)
Convective Transport of Energy
283(1)
Work Associated with Molecular Motions
284(6)
Questions for Discussion
286(1)
Problems
287(3)
Shell Energy Balances and Temperature Distributions in Solids and Laminar Flow
290(43)
Shell Energy Balances; Boundary Conditions
291(1)
Heat Conduction with an Electrical Heat Source
292(4)
Voltage Required for a Given Temperature Rise in a Wire Heated by an Electric Current
295(1)
Heated Wire with Specified Heat Transfer Coefficient and Ambient Air Temperature
295(1)
Heat Conduction with a Nuclear Heat Source
296(2)
Heat Conduction with a Viscous Heat Source
298(2)
Heat Conduction with a Chemical Heat Source
300(3)
Heat Conduction through Composite Walls
303(4)
Composite Cylindrical Walls
305(2)
Heat Conduction in a Cooling Fin
307(3)
Error in Thermocouple Measurement
309(1)
Forced Convection
310(6)
Free Convection
316(17)
Questions for Discussion
319(1)
Problems
320(13)
The Equations of Change for Nonisothermal Systems
333(41)
The Energy Equation
333(3)
Special Forms of the Energy Equation
336(2)
The Boussinesq Equation of Motion for Forced and Free Convection
338(1)
Use of the Equations of Change to Solve Steady-State Problems
339(14)
Steady-State Forced-Convection Heat Transfer in Laminar Flow in a Circular Tube
342(1)
Tangential Flow in an Annulus with Viscous Heat Generation
342(1)
Steady Flow in a Nonisothermal Film
343(1)
Transpiration Cooling
344(2)
Free Convection Heat Transfer from a Vertical Plate
346(3)
Adiabatic Frictionless Processes in an Ideal Gas
349(1)
One-Dimensional Compressible Flow: Velocity, Temperature, and Pressure Profiles in a Stationary Shock Wave
350(3)
Dimensional Analysis of the Equations of Change for Nonisothermal Systems
353(21)
Temperature Distribution about a Long Cylinder
356(2)
Free Convection in a Horizontal Fluid Layer; Formation of Benard Cells
358(2)
Surface Temperature of an Electrical Heating Coil
360(1)
Questions for Discussion
361(1)
Problems
361(13)
Temperature Distributions with More than One Independent Variable
374(33)
Unsteady Heat Conduction in Solids
374(7)
Heating of a Semi-Infinite Slab
375(1)
Heating of a Finite Slab
376(3)
Unsteady Heat Conduction near a Wall with Sinusoidal Heat Flux
379(1)
Cooling of a Sphere in Contact with a Well-Stirred Fluid
379(2)
Steady Heat Conduction in Laminar, Incompressible Flow
381(4)
Laminar Tube Flow with Constant Heat Flux at the Wall
383(1)
Laminar Tube Flow with Constant Heat Flux at the Wall: Asymptotic Solution for the Entrance Region
384(1)
Steady Potential Flow of Heat in Solids
385(2)
Temperature Distribution in a Wall
386(1)
Boundary Layer Theory for Nonisothermal Flow
387(20)
Heat Transfer in Laminar Forced Convection along a Heated Flat Plate (the von Karman Integral Method)
388(3)
Heat Transfer in Laminar Forced Convection along a Heated Flat Plate (Asymptotic Solution for Large Prandtl Numbers)
391(1)
Forced Convection in Steady Three-Dimensional Flow at High Prandtl Numbers
392(2)
Questions for Discussion
394(1)
Problems
395(12)
Temperature Distributions in Turbulent Flow
407(15)
Time-Smoothed Equations of Change for Incompressible Nonisothermal Flow
407(2)
The Time-Smoothed Temperature Profile near a Wall
409(1)
Empirical Expressions for the Turbulent Heat Flux
410(1)
An Approximate Relation for the Wall Heat Flux for Turbulent Flow in a Tube
411(1)
Temperature Distribution for Turbulent Flow in Tubes
411(4)
Temperature Distribution for Turbulent Flow in Jets
415(1)
Fourier Analysis of Energy Transport in Tube-Flow at Large Prandtl Numbers
416(6)
Questions for Discussion
421(1)
Problems
421(1)
Interphase Transport in Nonisothermal Systems
422(32)
Definitions of Heat Transfer Coefficients
423(5)
Calculation of Heat Transfer Coefficients from Experimental Data
426(2)
Analytical Calculation of Heat Transfer Coefficients for Forced Convection through Tubes and Slits
428(5)
Heat Transfer Coefficients for Forced Convection in Tubes
433(5)
Design of a Tubular Heater
437(1)
Heat Transfer Coefficients for Forced Convection around Submerged Objects
438(3)
Heat Transfer Coefficients for Forced Convection through Packed Beds
441(1)
Heat Transfer Coefficients for Free and Mixed Convection
442(4)
Heat Loss by Free Convection from a Horizontal Pipe
445(1)
Heat Transfer Coefficients for Condensation of Pure Vapors on Solid Surfaces
446(8)
Condensation of Steam on a Vertical Surface
449(1)
Questions for Discussion
449(1)
Problems
450(4)
Macroscopic Balances for Nonisothermal Systems
454(33)
The Macroscopic Energy Balance
455(1)
The Macroscopic Mechanical Energy Balance
456(2)
Use of the Macroscopic Balances to Solve Steady-State Problems with Flat Velocity Profiles
458(3)
The Cooling of an Ideal Gas
459(1)
Mixing of Two Ideal Gas Streams
460(1)
The d-Forms of the Macroscopic Balances
461(4)
Parallel- or Counter-Flow Heat Exchangers
462(2)
Power Requirement for Pumping a Compressible Fluid through a Long Pipe
464(1)
Use of the Macroscopic Balances to Solve Unsteady-State Problems and Problems with Nonflat Velocity Profiles
465(22)
Heating of a Liquid in an Agitated Tank
466(2)
Operation of a Simple Temperature Controller
468(3)
Flow of Compressible Fluids through Heat Meters
471(1)
Free Batch Expansion of a Compressible Fluid
472(2)
Questions for Discussion
474(1)
Problems
474(13)
Energy Transport by Radiation
487(26)
The Spectrum of Electromagnetic Radiation
488(2)
Absorption and Emission at Solid Surfaces
490(3)
Planck's Distribution Law, Wien's Displacement Law, and the Stefan-Boltzmann Law
493(4)
Temperature and Radiation-Energy Emission of the Sun
496(1)
Direct Radiation between Black Bodies in Vacuo at Different Temperatures
497(5)
Estimation of the Solar Constant
501(1)
Radiant Heat Transfer between Disks
501(1)
Radiation between Nonblack Bodies at Different Temperatures
502(4)
Radiation Shields
503(1)
Radiation and Free-Convection Heat Losses from a Horizontal Pipe
504(1)
Combined Radiation and Convection
505(1)
Radiant Energy Transport in Absorbing Media
506(7)
Absorption of a Monochromatic Radiant Beam
507(1)
Questions for Discussion
508(1)
Problems
508(5)
Part III Mass Transport
Diffusivity and the Mechanisms of Mass Transport
513(30)
Fick's Law of Binary Diffusion (Molecular Mass Transport)
514(7)
Diffusion of Helium through Pyrex Glass
519(1)
The Equivalence of D and D
520(1)
Temperature and Pressure Dependence of Diffusivities
521(4)
Estimation of Diffusivity at Low Density
523(1)
Estimation of Self-Diffusivity at High Density
523(1)
Estimation of Binary Diffusivity at High Density
524(1)
Theory of Diffusion in Gases at Low Density
525(3)
Computation of Mass Diffusivity for Low-Density Monatomic Gases
528(1)
Theory of Diffusion in Binary Liquids
528(3)
Estimation of Liquid Diffusivity
530(1)
Theory of Diffusion in Colloidal Suspensions
531(1)
Theory of Diffusion in Polymers
532(1)
Mass and Molar Transport by Convection
533(3)
Summary of Mass and Molar Fluxes
536(2)
The Maxwell-Stefan Equations for Multicomponent Diffusion in Gases at Low Density
538(5)
Questions for Discussion
538(1)
Problems
539(4)
Concentration Distributions in Solids and Laminar Flow
543(39)
Shell Mass Balances; Boundary Conditions
545(1)
Diffusion through a Stagnant Gas Film
545(6)
Diffusion with a Moving Interface
549(1)
Determination of Diffusivity
549(1)
Diffusion through a Nonisothermal Spherical Film
550(1)
Diffusion with a Heterogeneous Chemical Reaction
551(3)
Diffusion with a Slow Heterogeneous Reaction
553(1)
Diffusion with a Homogeneous Chemical Reaction
554(4)
Gas Absorption with Chemical Reaction in an Agitated Tank
555(3)
Diffusion into a Falling Liquid Film (Gas Absorption)
558(4)
Gas Absorption from Rising Bubbles
560(2)
Diffusion into a Falling Liquid Film (Solid Dissolution)
562(1)
Diffusion and Chemical Reaction inside a Porous Catalyst
563(4)
Diffusion in a Three-Component Gas System
567(15)
Questions for Discussion
568(1)
Problems
568(14)
Equations of Change for Multicomponent Systems
582(30)
The Equations of Continuity for a Multicomponent Mixture
582(4)
Diffusion, Convection, and Chemical Reaction
585(1)
Summary of the Multicomponent Equations of Change
586(4)
Summary of the Multicomponent Fluxes
590(2)
The Partial Molar Enthalpy
591(1)
Use of the Equations of Change for Mixtures
592(7)
Simultaneous Heat and Mass Transport
592(3)
Concentration Profile in a Tubular Reactor
595(1)
Catalytic Oxidation of Carbon Monoxide
596(2)
Thermal Conductivity of a Polyatomic Gas
598(1)
Dimensional Analysis of the Equations of Change for Nonreacting Binary Mixtures
599(13)
Concentration Distribution about a Long Cylinder
601(1)
Fog Formation during Dehumidification
602(2)
Blending of Miscible Fluids
604(1)
Questions for Discussion
605(1)
Problems
606(6)
Concentration Distributions with More than One Independent Variable
612(45)
Time-Dependent Diffusion
613(10)
Unsteady-State Evaporation of a Liquid (the ``Arnold Problem'')
613(4)
Gas Absorption with Rapid Reaction
617(2)
Unsteady Diffusion with First-Order Homogeneous Reaction
619(2)
Influence of Changing Interfacial Area on Mass Transfer at an Interface
621(2)
Steady-State Transport in Binary Boundary Layers
623(10)
Diffusion and Chemical Reaction in Isothermal Laminar Flow along a Soluble Flat Plate
625(2)
Forced Convection from a Flat Plate at High Mass-Transfer Rates
627(5)
Approximate Analogies for the Flat Plate at Low Mass-Transfer Rates
632(1)
Steady-State Boundary-Layer Theory for Flow around Objects
633(4)
Mass Transfer for Creeping Flow around a Gas Bubble
636(1)
Boundary Layer Mass Transport with Complex Interfacial Motion
637(6)
Mass Transfer with Nonuniform Interfacial Deformation
641(1)
Gas Absorption with Rapid Reaction and Interfacial Deformation
642(1)
``Taylor Dispersion'' in Laminar Tube Flow
643(14)
Questions for Discussion
647(1)
Problems
648(9)
Concentration Distributions in Turbulent Flow
657(14)
Concentration Fluctuations and the Time-Smoothed Concentration
657(1)
Time-Smoothing of the Equation of Continuity of A
658(1)
Semi-Empirical Expressions for the Turbulent Mass Flux
659(1)
Enhancement of Mass Transfer by a First-Order Reaction in Turbulent Flow
659(4)
Turbulent Mixing and Turbulent Flow with Second-Order Reaction
663(8)
Questions for Discussion
667(1)
Problems
668(3)
Interphase Transport in Nonisothermal Mixtures
671(55)
Definition of Transfer Coefficients in One Phase
672(4)
Analytical Expressions for Mass Transfer Coefficients
676(3)
Correlation of Binary Transfer Coefficients in One Phase
679(8)
Evaporation from a Freely Falling Drop
682(1)
The Wet and Dry Bulb Psychrometer
683(2)
Mass Transfer in Creeping Flow through Packed Beds
685(2)
Mass Transfer to Drops and Bubbles
687(1)
Definition of Transfer Coefficients in Two Phases
687(7)
Determination of the Controlling Resistance
690(1)
Interaction of Phase Resistances
691(2)
Area Averaging
693(1)
Mass Transfer and Chemical Reactions
694(4)
Estimation of the Interfacial Area in a Packed Column
694(1)
Estimation of Volumetric Mass Transfer Coefficients
695(1)
Model-Insensitive Correlations for Absorption with Rapid Reaction
696(2)
Combined Heat and Mass Transfer by Free Convection
698(1)
Additivity of Grash of Numbers
698(1)
Free-Convection Heat Transfer as a Source of Forced-Convection Mass Transfer
698(1)
Effects of Interfacial Forces on Heat and Mass Transfer
699(4)
Elimination of Circulation in a Rising Gas Bubble
701(1)
Marangoni Instability in a Falling Film
702(1)
Transfer Coefficients at High Net Mass Transfer Rates
703(13)
Rapid Evaporation of a Liquid from a Plane Surface
710(1)
Correction Factors in Droplet Evaporation
711(1)
Wet-Bulb Performance Corrected for Mass-Transfer Rate
711(1)
Comparison of Film and Penetration Models for Unsteady Evaporation in a Long Tube
712(1)
Concentration Polarization in Ultrafiltration
713(3)
Matrix Approximations for Multicomponent Mass Transport
716(10)
Questions for Discussion
721(1)
Problems
722(4)
Macroscopic Balances for Multicomponent Systems
726(38)
The Macroscopic Mass Balances
727(11)
Disposal of an Unstable Waste Product
728(2)
Binary Splitters
730(1)
The Macroscopic Balances and Dirac's ``Separative Capacity'' and ``Value Function''
731(2)
Compartmental Analysis
733(3)
Time Constants and Model Insensitivity
736(2)
The Macroscopic Momentum and Angular Momentum Balances
738(1)
The Macroscopic Energy Balance
738(1)
The Macroscopic Mechanical Energy Balance
739(1)
Use of the Macroscopic Balances to Solve Steady-State Problems
739(13)
Energy Balances for a Sulfur Dioxide Converter
739(3)
Height of a Packed-Tower Absorber
742(4)
Linear Cascades
746(3)
Expansion of a Reactive Gas Mixture through a Frictionless Adiabatic Nozzle
749(3)
Use of the Macroscopic Balances to Solve Unsteady-State Problems
752(12)
Start-Up of a Chemical Reactor
752(1)
Unsteady Operation of a Packed Column
753(3)
The Utility of Low-Order Moments
756(2)
Questions for Discussion
758(1)
Problems
759(5)
Other Machanisms for Mass Transport
764(41)
The Equation of Change for Entropy
765(2)
The Flux Expressions for Heat and Mass
767(7)
Thermal Diffusion and the Clusius-Dickel Column
770(2)
Pressure Diffusion and the Ultracentrifuge
772(2)
Concentration Diffusion and Driving Forces
774(1)
Applications of the Generalized Maxwell-Stefan Equations
775(10)
Centrifugation of Proteins
776(3)
Proteins as Hydrodynamic Particles
779(1)
Diffusion of Salts in an Aqueous Solution
780(2)
Departures from Local Electroneutrality: Electro-Osmosis
782(2)
Additional Mass-Transfer Driving Forces
784(1)
Mass Transport across Selectively Permeable Membranes
785(8)
Concentration Diffusion between Preexisting Bulk Phases
788(1)
Ultrafiltration and Reverse Osmosis
789(2)
Charged Membrance and Donnan Exclusion
791(2)
Mass Transport in Porous Media
793(12)
Knudsen Diffusion
795(2)
Transport from a Binary External Solution
797(1)
Questions for Discussion
798(1)
Problems
799(6)
Postface 805(67)
Appendices
Appendix A Vector and Tensor Notation
807(36)
A.1 Vector Operations from a Geometrical Viewpoint
808(2)
A.2 Vector Operations in Terms of Components
810(4)
A.2-1 Proof of a Vector Identity
814(1)
A.3 Tensor Operations in Terms of Components
815(4)
A.4 Vector and Tensor Differential Operations
819(3)
A.4-1 Proof of a Tensor Identity
822(2)
A.5 Vector and Tensor Integral Theorems
824(1)
A.6 Vector and Tensor Algebra in Curvilinear Coordinates
825(4)
A.7 Differential Operations in Curvilinear Coordinates
829(2)
A.7-1 Differential Operations in Cylindrical Coordinates
831(7)
A.7-2 Differential Operations in Spherical Coordinates
838(1)
A.8 Integral Operations in Curvilinear Coordinates
839(2)
A.9 Further Comments on Vector-Tensor Notation
841(2)
Appendix B Fluxes and the Equations of Change
843(9)
B.1 Newton's Law of Viscosity
843(2)
B.2 Fourier's Law of Heat Conduction
845(1)
B.3 Fick's (First) Law of Binary Diffusion
846(1)
B.4 The Equation of Continuity
846(1)
B.5 The Equation of Motion in Terms of τ
847(1)
B.6 The Equation of Motion for a Newtonian Fluid with Constant p and μ
848(1)
B.7 The Dissipation Function &thetas; for Newtonian Fluids
849(1)
B.8 The Equation of Energy in Terms of q
849(1)
B.9 The Equation of Energy for Pure Newtonian Fluids with Constant p and k
850(1)
B.10 The Equation of Continuity for Species α in Terms of jα
850(1)
B.11 The Equation of Continuity for Species A in Terms of ω for Constant pD
851(1)
Appendix C Mathematical Topics
852(6)
C.1 Some Ordinary Differential Equations and Their Solutions
852(1)
C.2 Expansions of Functions in Taylor Series
853(1)
C.3 Differentiation of Integrals (the Leibniz Formula)
854(1)
C.4 The Gamma Function
855(1)
C.5 The Hyperbolic Functions
856(1)
C.6 The Error Function
857(1)
Appendix D The Kinetic Theory of Gases
858(5)
D.1 The Boltzmann Equation
858(1)
D.2 The Equations of Change
859(1)
D.3 The Molecular Expressions for the Fluxes
859(1)
D.4 The Solution to the Boltzmann Equation
860(1)
D.5 The Fluxes in Terms of the Transport Properties
860(1)
D.6 The Transport Properties in Terms of the Intermolecular Forces
861(1)
D.7 Concluding Comments
861(2)
Appendix E Tables for Prediction of Transport Properties
863(4)
E.1 Intermolecular Force Parameters and Critical Properties
864(2)
E.2 Functions for Prediction of Transport Properties of Gases at Low Densities
866(1)
Appendix F Constants and Conversion Factors
867(5)
F.1 Mathematical Constants
867(1)
F.2 Physical Constants
867(1)
F.3 Conversion Factors
868(4)
Notation 872(5)
Author Index 877(8)
Subject Index 885

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