Thermal Radiation Heat Transfer  book cover
6th Edition

Thermal Radiation Heat Transfer

ISBN 9781466593268
Published July 28, 2015 by CRC Press
1016 Pages - 646 B/W Illustrations

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Book Description

Explore the Radiative Exchange between Surfaces

Further expanding on the changes made to the fifth edition, Thermal Radiation Heat Transfer, 6th Edition continues to highlight the relevance of thermal radiative transfer and focus on concepts that develop the radiative transfer equation (RTE).

The book explains the fundamentals of radiative transfer, introduces the energy and radiative transfer equations, covers a variety of approaches used to gauge radiative heat exchange between different surfaces and structures, and provides solution techniques for solving the RTE.

What’s New in the Sixth Edition

This revised version updates information on properties of surfaces and of absorbing/emitting/scattering materials, radiative transfer among surfaces, and radiative transfer in participating media. It also enhances the chapter on near-field effects, addresses new applications that include enhanced solar cell performance and self-regulating surfaces for thermal control, and updates references.

Comprised of 17 chapters, this text:

  • Discusses the fundamental RTE and its simplified forms for different medium properties
  • Presents an intuitive relationship between the RTE formulations and the configuration factor analyses
  • Explores the historical development and the radiative behavior of a blackbody
  • Defines the radiative properties of solid opaque surfaces
  • Provides a detailed analysis and solution procedure for radiation exchange analysis
  • Contains methods for determining the radiative flux divergence (the radiative source term in the energy equation)

Thermal Radiation Heat Transfer, 6th Edition explores methods for solving the RTE to determine the local spectral intensity, radiative flux, and flux gradient. This book enables you to assess and calculate the exchange of energy between objects that determine radiative transfer at different energy levels.

Table of Contents

Introduction to Radiative Transfer
Importance of Thermal Radiation in Engineering
Thermal Energy Transfer
Thermal Radiative Transfer
Radiative Energy Exchange and Radiative Intensity
Characteristics of Emission
Radiative Energy along a Line-of-Sight
Radiative Transfer Equation
Radiative Transfer in Enclosures with Nonparticipating Media
Concluding Remarks and Historical Notes
Radiative Properties at Interfaces
Transmissivity at an Interface
Relations among Reflectivity, Absorptivity, Emissivity, and Transmissivity
Radiative Properties of Opaque Materials
Electromagnetic Wave Theory Predictions
Extensions of the Theory for Radiative Properties
Measured Properties of Real Dielectric Materials
Measured Properties of Metals
Selective and Directional Opaque Surfaces
Concluding Remarks
Configuration Factors for Diffuse Surfaces with Uniform Radiosity
Radiative Transfer Equation for Surfaces Separated by a Transparent Medium
Geometric Configuration Factors between Two Surfaces
Methods for Determining Configuration Factors
Constraints on Configuration Factor Accuracy
Compilation of Known Configuration Factors and Their References: Appendix C and Web Catalog
Radiation Exchange in Enclosures Composed of Black and/or Diffuse-Gray Surfaces
Radiative Transfer for Black Surfaces
Radiation between Finite Diffuse-Gray Areas
Radiation Analysis Using Infinitesimal Areas
Computer Programs for Enclosure Analysis
Exchange of Thermal Radiation among Nondiffuse Nongray Surfaces
Enclosure Theory for Diffuse Nongray Surfaces
Directional-Gray Surfaces
Surfaces with Directionally and Spectrally Dependent Properties
Radiation Exchange in Enclosures with Specularly Reflecting Surfaces
Net-Radiation Method in Enclosures Having Both Specular and Diffuse Reflecting Surfaces
Multiple Radiation Shields
Concluding Remarks
Radiation Combined with Conduction and Convection at Boundaries
Energy Relations and Boundary Conditions
Radiation Transfer with Conduction Boundary Conditions
Radiation with Convection and Conduction
Numerical Solution Methods
Numerical Integration Methods for Use with Enclosure Equations
Numerical Formulations for Combined-Mode Energy Transfer
Numerical Solution Techniques
Monte Carlo Method
Concluding Remarks
Inverse Problems in Radiative Heat Transfer
Introduction to Inverse Problems
General Inverse Solution Methods
Comparison of Methods for a Particular Problem
Application of Metaheuristic Methods
Unresolved Problems
Inverse Problems at the Nanoscale
Inverse Problems Involving Participating Media
Concluding Remarks
Properties of Absorbing and Emitting Media
Spectral Lines and Bands for Gas Absorption and Emission
Band Models and Correlations for Gas Absorption and Emission
Gas Total Emittance Correlations
True Absorption Coefficient
Radiative Properties of Translucent Liquids and Solids
Fundamental Radiative Transfer Relations
Energy Equation and Boundary Conditions for a Participating Medium
Radiative Transfer and Source-Function Equations
Radiative Flux and Its Divergence within a Medium
Summary of Relations for Radiative Transfer in Absorbing, Emitting, and Scattering Media
Treatment of Radiation Transfer in Non-LTE Media
Net Radiation Method for Enclosures Filled with an Isothermal Medium of Uniform Composition
Evaluation of Spectral Geometric-Mean Transmittance and Absorptance Factors
Mean Beam Length Approximation for Spectral Radiation from an Entire Volume of a Medium to All or Part of Its Boundary
Exchange of Total Radiation in an Enclosure by Use of Mean Beam Length
Optically Thin and Cold Media
Radiative Transfer in Plane Layers and Multidimensional Geometries
Radiative Intensity, Flux, Flux Divergence, and Source Function in a Plane Layer
Gray Plane Layer of Absorbing and Emitting Medium with Isotropic Scattering
Gray Plane Layer in Radiative Equilibrium
Multidimensional Radiation in a Participating Gray Medium with Isotropic Scattering
Solution Methods for Radiative Transfer in Participating Media
Series Expansion and Moment Methods
Discrete Ordinates (SN) Method
Other Methods That Depend on Angular Discretization
Zonal Method
Monte Carlo Technique for Radiatively Participating Media
Additional Solution Methods
Comparison of Results for the Methods
Benchmark Solutions for Computational Verification
Inverse Problems Involving Participating Media
Use of Mean Absorption Coefficients
Solution Using Commercial Codes
Conjugate Heat Transfer in Participating Media
Radiation Combined with Conduction
Transient Solutions Including Conduction
Combined Radiation, Conduction, and Convection in a Boundary Layer
Numerical Solution Methods for Combined Radiation, Conduction, and Convection in Participating Media
Combined Radiation, Convection, and Conduction Heat Transfer
Inverse Multimode Problems
Verification, Validation, and Uncertainty Quantification
Electromagnetic Wave Theory
EM Wave Equations
Wave Propagation in a Medium
Laws of Reflection and Refraction
Amplitude and Scattering Matrices
EM Wave Theory and the Radiative Transfer Equation
Absorption and Scattering by Particles and Agglomerates
Absorption and Scattering: Definitions
Scattering by Spherical Particles
Scattering by Small Particles
Lorenz-Mie Theory for Spherical Particles
Prediction of Properties for Irregularly Shaped Particles
Approximate Anisotropic Scattering Phase Functions
Dependent Absorption and Scattering
Near-Field Thermal Radiation
Electromagnetic Treatment of Thermal Radiation and Basic Concepts
Evanescent and Surface Waves
Near-Field Radiative Heat Flux Calculations
Computational Studies of Near-Field Thermal Radiation
Experimental Studies of Near-Field Thermal Radiation
Concluding Remarks
Radiative Effects in Translucent Solids, Windows, and Coatings
Transmission, Absorption, and Reflection of Windows
Enclosure Analysis with Partially Transparent Windows
Effects of Coatings or Thin Films on Surfaces
Refractive Index Effects on Radiation in a Participating Medium
Multiple Participating Layers with Heat Conduction
Light Pipes and Fiber Optics
Final Remarks
A: Conversion Factors, Radiation Constants, and Blackbody Functions
B: Radiative Properties
Catalog of Selected Configuration Factors
Exponential Integral Relations and Two-Dimensional Radiation Functions
E: References

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John R. Howell received his academic degrees from Case Western Reserve University (Case Institute of Technology), Cleveland, Ohio. He began his engineering career as a researcher at NASA Lewis (Glenn) Research Center (1961–1968) and then took academic positions at the University of Houston (1978–1988) and the University of Texas at Austin, where he remained until retirement in 2012. He is presently Ernest Cockrell, Jr., Memorial Chair emeritus at The University of Texas.

Howell pioneered the use of the Monte Carlo method for the analysis of radiative heat transfer in complex systems that contain absorbing, emitting, and scattering media.

Robert Siegel received his ScD in mechanical engineering from Massachusetts Institute of Technology in 1953. For two years he worked at General Electric Company in the Heat Transfer Consulting Office and on analyzing the heat transfer characteristics of the Seawolf submarine nuclear reactor. He joined NASA in 1955 and was a senior research scientist at the Lewis/Glenn Research Center until he retired in 1999. He was an associate editor for the Journal of Heat Transfer and the Journal of Thermophysics and Heat Transfer. He has written numerous papers, and given graduate heat transfer courses as an adjunct professor at three universities.

M. Pinar Mengüç completed his BSc and MS in mechanical engineering from the Middle East Technical University (METU) in Ankara, Turkey. He earned his PhD in mechanical engineering from Purdue University in 1985. He joined the University of Kentucky in 1985 and was promoted to associate and full professor in 1988 and 1993, respectively. In 2008, he became an Engineering Alumni Association professor .. In 2011 he joined Özyegin University in Istanbul as the founding head of the Mechanical Engineering Department and founding director of the Center for Energy, Environment, and Economy (CEEE).


"This classical text, which has inspired generations of heat transfer students and researchers, has been updated and improved to make its content current with valuable online resources. The book covers very fundamental concepts of thermal radiation and radiative transport in participating and nonparticipating media, recent advances in inverse problems and near-field thermal radiation, and real-world applications including solar energy conversion."
—Zhuomin Zhang, Woodruff School of Mechanical Engineering, Georgia Institute of Technology, Atlanta, USA

"The most complete and wide cover of all aspects of radiative transfer. Clear explanations. Very good exercises."
—Vladimir Solovjov (Soloviev), Mechanical Engineering Department, BYU

"A new edition of this well-known textbook is always considered as a major event. Once again, this new edition of the ‘’Howell – Siegel – Mengüç’’ textbook on thermal radiation heat transfer will prove to be indispensable and a gold mine for students, engineers and researchers. … new comers to thermal radiation and already experts will surely be very contended with this new edition."
—Rodolphe Vaillon, CNRS

"In general, the material strikes a good balance between providing the student a high level pedagogical explanation of complex phenomena, while retaining the details needed for implementing modern solution techniques. The textbook is an invaluable resource for teaching graduate students, and an excellent reference for the experienced researcher."
—Kyle Daun, University of Waterloo

"This text is a classic in radiation heat transfer. The new edition is updated with better arrangement in numerical solution methods of radiative transfer equation coupled with conduction and/or convection heat transfer and gas radiation properties. The organization is more logical and streamlined. The treatment maintains the comprehensive and fundamental nature of this text."
—Pei-feng Hsu, Florida Institute of Technology

"This book is a classic. I learned about radiation heat transfer from it years ago and with all the improvements made, it is still probably the best for the students of today to learn about radiation. The coverage is encyclopedic, yet every topic is explained clearly and in great detail. Chapters also include figures, data, examples and exercises that make the book useful as a text."
—Ernesto Gutierrez-Miravete, Professor of Practice

"… Professor M. Pinar Mengüç has joined the team of authors, contributing with his extensive expertise in radiative heat transfer. Thus Thermal Radiation Heat Transfer is since authored by Howell, Siegel and Mengüç. The new team with its reinforced skills assures a bright future for the book."
—Jean-François Sacadura, INSA Lyon – France

"… a successful combination of well-known formalisms and up-to-date solutions and data that the radiative transfer community offers through modern papers and conferences. Hence, the reader can find the classical descriptions of the most often used methods, plus the updated derivations which extend these methods. … useful both for engineers and researchers, from practical applications to modern developments."
—Pascal Boulet, Professor at Université de Lorraine, France

"… a really great resource for engineers and researchers on radiative heat transfer, for beginners but also for more advanced readers. It improves at each new edition and reflects the most recent developments on radiative transfer. It is undoubtedly the most comprehensive resource on the topic …"
—Dr. Frederic Andre, CNRS

"… updates the coverage of this authoritative textbook and completes an excellent textbook for graduate classes on radiation heat transfer. … an extremely helpful resource to researchers, engineers and scientists in the Field of thermal radiation."
—Costas Grigoropoulos, University of California, Berkeley

"… In a few words: this book altogether offers a complete and clear vision of thermal radiation and a detailed analysis of any specific process it involves. I find it enormously helpful for anyone approaching the domain, at any level."
—Denis Lemonnier, Institut Prime, CNRS / ISAE-ENSMA / Univ. of Poitiers

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