Heat conduction.

"This book supplies the long awaited revision of the bestseller on heat conduction, replacing some of the coverage of numerical methods with content on micro- and nano-scale heat transfer. Extensive problems, cases, and examples have been thoroughly updated, and a solutions manual is available&...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Hahn, David W., 1964-
Otros Autores: Özışık, M. Necati
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken, N.J. : Wiley, 2012.
Edición:3rd ed. /
Temas:
Heat > Conduction.
Chaleur > Conduction.
SCIENCE > Mechanics > Dynamics > Thermodynamics.
Heat > Conduction
Acceso en línea:Texto completo

MARC

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100 1 |a Hahn, David W.,  |d 1964-  |1 https://id.oclc.org/worldcat/entity/E39PCjGCqhkWdWtxb3hGd6rRBq 
245 1 0 |a Heat conduction. 
250 |a 3rd ed. /  |b David W. Hahn, M. Necati Özışık. 
260 |a Hoboken, N.J. :  |b Wiley,  |c 2012. 
300 |a 1 online resource 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
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500 |a Revised edition of: Heat conduction / M. Necati Özisik. 2nd ed. c1993. 
520 |a "This book supplies the long awaited revision of the bestseller on heat conduction, replacing some of the coverage of numerical methods with content on micro- and nano-scale heat transfer. Extensive problems, cases, and examples have been thoroughly updated, and a solutions manual is available"--  |c Provided by publisher. 
504 |a Includes bibliographical references and index. 
588 0 |a Print version record and CIP data provided by publisher. 
505 0 |a 1. Heat Conduction Fundamentals -- 2. Orthogonal Functions, Boundary Value Problems, and the Fourier Series -- 3. Separation of Variables in the Rectangular Coordinate System -- 4. Separation of Variables in the Cylindrical Coordinate System -- 5. Separation of Variables in the Spherical Coordinate System -- 6. Solution of the Heat Equation for Semi-Infinite and Infinite Domains -- 7. Use of Duhamel's Theorem -- 8. Use of Green's Function for Solution of Heat Conduction Problems -- 9. Use of the Laplace Transform -- 10. One-Dimensional Composite Medium -- 11. Moving Heat Source Problems -- 12. Phase-Change Problems -- 13. Approximate Analytic Methods -- 14. Integral Transform Technique -- 15. Heat Conduction in Anisotropic Solids -- 16. Introduction to Microscale Heat Conduction. 
505 0 0 |g 1.  |t Heat Conduction Fundamentals --  |g 1.1.  |t The Heat Flux --  |g 1.2.  |t Thermal Conductivity --  |g 1.3.  |t Differential Equation of Heat Conduction --  |g 1.4.  |t Fourier's Law and the Heat Equation in Cylindrical and Spherical Coordinate Systems --  |g 1.5.  |t General Boundary Conditions and Initial Condition for the Heat Equation --  |g 1.6.  |t Nondimensional Analysis of the Heat Conduction Equation --  |g 1.7.  |t Heat Conduction Equation for Anisotropic Medium --  |g 1.8.  |t Lumped and Partially Lumped Formulation --  |g 2.  |t Orthogonal Functions, Boundary Value Problems, and the Fourier Series --  |g 2.1.  |t Orthogonal Functions --  |g 2.2.  |t Boundary Value Problems --  |g 2.3.  |t The Fourier Series --  |g 2.4.  |t Computation of Eigenvalues --  |g 2.5.  |t Fourier Integrals --  |g 3.  |t Separation of Variables in the Rectangular Coordinate System --  |g 3.1.  |t Basic Concepts in the Separation of Variables Method --  |g 3.2.  |t Generalization to Multidimensional Problems --  |g 3.3.  |t Solution of Multidimensional Homogenous Problems --  |g 3.4.  |t Multidimensional Nonhomogeneous Problems: Method of Superposition --  |g 3.5.  |t Product Solution --  |g 3.6.  |t Capstone Problem --  |g 4.  |t Separation of Variables in the Cylindrical Coordinate System --  |g 4.1.  |t Separation of Heat Conduction Equation in the Cylindrical Coordinate System --  |g 4.2.  |t Solution of Steady-State Problems --  |g 4.3.  |t Solution of Transient Problems --  |g 4.4.  |t Capstone Problem --  |g 5.  |t Separation of Variables in the Spherical Coordinate System --  |g 5.1.  |t Separation of Heat Conduction Equation in the Spherical Coordinate System --  |g 5.2.  |t Solution of Steady-State Problems --  |g 5.3.  |t Solution of Transient Problems --  |g 5.4.  |t Capstone Problem --  |g 6.  |t Solution of the Heat Equation for Semi-Infinite and Infinite Domains --  |g 6.1.  |t One-Dimensional Homogeneous Problems in a Semi-Infinite Medium for the Cartesian Coordinate System --  |g 6.2.  |t Multidimensional Homogeneous Problems in a Semi-Infinite Medium for the Cartesian Coordinate System --  |g 6.3.  |t One-Dimensional Homogeneous Problems in An Infinite Medium for the Cartesian Coordinate System --  |g 6.4.  |t One-Dimensional homogeneous Problems in a Semi-Infinite Medium for the Cylindrical Coordinate System --  |g 6.5.  |t Two-Dimensional Homogeneous Problems in a Semi-Infinite Medium for the Cylindrical Coordinate System --  |g 6.6.  |t One-Dimensional Homogeneous Problems in a Semi-Infinite Medium for the Spherical Coordinate System --  |g 7.  |t Use of Duhamel's Theorem --  |g 7.1.  |t Development of Duhamel's Theorem for Continuous Time-Dependent Boundary Conditions --  |g 7.2.  |t Treatment of Discontinuities --  |g 7.3.  |t General Statement of Duhamel's Theorem --  |g 7.4.  |t Applications of Duhamel's Theorem --  |g 7.5.  |t Applications of Duhamel's Theorem for Internal Energy Generation --  |g 8.  |t Use of Green's Function for Solution of Heat Conduction Problems --  |g 8.1.  |t Green's Function Approach for Solving Nonhomogeneous Transient Heat Conduction --  |g 8.2.  |t Determination of Green's Functions --  |g 8.3.  |t Representation of Point, Line, and Surface Heat Sources with Delta Functions --  |g 8.4.  |t Applications of Green's Function in the Rectangular Coordinate System --  |g 8.5.  |t Applications of Green's Function in the Cylindrical Coordinate System --  |g 8.6.  |t Applications of Green's Function in the Spherical Coordinate System --  |g 8.7.  |t Products of Green's Functions --  |g 9.  |t Use of the Laplace Transform --  |g 9.1.  |t Definition of Laplace Transformation --  |g 9.2.  |t Properties of Laplace Transform --  |g 9.3.  |t Inversion of Laplace Transform Using the Inversion Tables --  |g 9.4.  |t Application of the Laplace Transform in the Solution of Time-Dependent Heat Conduction Problems --  |g 9.5.  |t Approximations for Small Times --  |g 10.  |t One-Dimensional Composite Medium --  |g 10.1.  |t Mathematical Formulation of One-Dimensional Transient Heat Conduction in a Composite Medium --  |g 10.2.  |t Transformation of Nonhomogeneous Boundary Conditions into Homogeneous Ones --  |g 10.3.  |t Orthogonal Expansion Technique for Solving M-Layer Homogeneous Problems --  |g 10.4.  |t Determination of Eigenfunctions and Eigenvalues --  |g 10.5.  |t Applications of Orthogonal Expansion Technique --  |g 10.6.  |t Green's Function Approach for Solving Nonhomogeneous Problems --  |g 10.7.  |t Use of Laplace Transform for Solving Semi-Infinite and Infinite Medium Problems --  |g 11.  |t Moving Heat Source Problems --  |g 11.1.  |t Mathematical Modeling of Moving Heat Source Problems --  |g 11.2.  |t One-Dimensional Quasi-Stationary Plane Heat Source Problem --  |g 11.3.  |t Two-Dimensional Quasi-Stationary Line Heat Source Problem --  |g 11.4.  |t Two-Dimensional Quasi-Stationary Ring Heat Source Problem --  |g 12.  |t Phase-Change Problems --  |g 12.1.  |t Mathematical Formulation of Phase-Change Problems --  |g 12.2.  |t Exact Solution of Phase-Change Problems --  |g 12.3.  |t Integral Method of Solution of Phase-Change Problems --  |g 12.4.  |t Variable Time Step Method for Solving Phase-Change Problems: A Numerical Solution --  |g 12.5.  |t Enthalpy Method for Solution of Phase-Change Problems: A Numerical Solution --  |g 13.  |t Approximate Analytic Methods --  |g 13.1.  |t Integral Method: Basic Concepts --  |g 13.2.  |t Integral Method: Application to Linear Transient Heat Conduction in a Semi-Infinite Medium --  |g 13.3.  |t Integral Method: Application to Nonlinear Transient Heat Conduction --  |g 13.4.  |t Integral Method: Application to a Finite Region --  |g 13.5.  |t Approximate Analytic Methods of Residuals --  |g 13.6.  |t The Galerkin Method --  |g 13.7.  |t Partial Integration --  |g 13.8.  |t Application to Transient Problems --  |g 14.  |t Integral Transform Technique --  |g 14.1.  |t Use of Integral Transform in the Solution of Heat Conduction Problems --  |g 14.2.  |t Applications in the Rectangular Coordinate System --  |g 14.3.  |t Applications in the Cylindrical Coordinate System --  |g 14.4.  |t Applications in the Spherical Coordinate System --  |g 14.5.  |t Applications in the Solution of Steady-state problems --  |g 15.  |t Heat Conduction in Anisotropic Solids --  |g 15.1.  |t Heat Flux for Anisotropic Solids --  |g 15.2.  |t Heat Conduction Equation for Anisotropic Solids --  |g 15.3.  |t Boundary Conditions --  |g 15.4.  |t Thermal Resistivity Coefficients --  |g 15.5.  |t Determination of Principal Conductivities and Principal Axes --  |g 15.6.  |t Conductivity Matrix for Crystal Systems --  |g 15.7.  |t Transformation of Heat Conduction Equation for Orthotropic Medium --  |g 15.8.  |t Some Special Cases --  |g 15.9.  |t Heat Conduction in an Orthotropic Medium --  |g 15.10.  |t Multidimensional Heat Conduction in an Anisotropic Medium --  |g 16.  |t Introduction to Microscale Heat Conduction --  |g 16.1.  |t Microstructure and Relevant Length Scales --  |g 16.2.  |t Physics of Energy Carriers --  |g 16.3.  |t Energy Storage and Transport --  |g 16.4.  |t Limitations of Fourier's Law and the First Regime of Microscale Heat Transfer --  |g 16.5.  |t Solutions and Approximations for the First Regime of Microscale Heat Transfer --  |g 16.6.  |t Second and Third Regimes of Microscale Heat Transfer --  |g 16.7.  |t Summary Remarks --  |g Appendix I.  |t Physical Properties --  |g Appendix II.  |t Roots of Transcendental Equations --  |g Appendix III.  |t Error Functions --  |g Appendix IV.  |t Bessel Functions --  |g Appendix V.  |t Numerical Values of Legendre Polynomials of the First Kind --  |g Appendix VI.  |t Properties of Delta Functions. 
590 |a ProQuest Ebook Central  |b Ebook Central Academic Complete 
650 0 |a Heat  |x Conduction. 
650 6 |a Chaleur  |x Conduction. 
650 7 |a SCIENCE  |x Mechanics  |x Dynamics  |x Thermodynamics.  |2 bisacsh 
650 7 |a Heat  |x Conduction  |2 fast 
700 1 |a Özışık, M. Necati. 
758 |i has work:  |a Heat conduction (Text)  |1 https://id.oclc.org/worldcat/entity/E39PCGQM8dPwRhP69mdD9XgX8d  |4 https://id.oclc.org/worldcat/ontology/hasWork 
776 0 8 |i Print version:  |a Hahn, David W., 1964-  |t Heat conduction.  |b 3rd ed. / David W. Hahn.  |d Hoboken, N.J. : Wiley, 2012  |z 9780470902936  |w (DLC) 2011052322 
856 4 0 |u https://ebookcentral.uam.elogim.com/lib/uam-ebooks/detail.action?docID=875843  |z Texto completo 
880 8 |6 505-00/(S  |a Table I-3 Physical Properties of Insulating Materials -- Appendix II Roots of Transcendental Equations -- Appendix III Error Functions -- Appendix IV Bessel Functions -- Table IV-1 Numerical Values of Bessel Functions -- Table IV-2 First 10 Roots of Jn(z) = 0, n = 0, 1, 2, 3, 4, 5 -- Table IV-3 First Six Roots of βJ1(β) − cJ0(β) = 0 -- Table IV-4 First Five Roots of J0(β)Y0(cβ) − Y0(β)J0(cβ) = 0 -- Appendix V Numerical Values of Legendre Polynomials of the First Kind -- Appendix VI Properties of Delta Functions -- Index. 
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