000			02855 a2200277 4500
999			_c5717 _d5717
005			20250801163758.0
008			250801b ||||| |||| 00| 0 eng d
020			_a9780367347079
041			_aeng
082			_a621.4022 HOW/T
100			_aHowell, John R. _91182
100			_aMengüc, M. Pinar _914222
100			_aDaun, Kyle J. _914223
100			_aSiegel, Robert _91187
245			_aThermal radiation heat transfer
250			_a7th ed.
260			_bCRC Press _aBoca Raton _c2021
300			_axxxiv, 1005p.; 26cm.
500			_aTable of Contents: 1. Introduction to Radiative Transfer. 2. Radiative Properties at Interfaces. 3. Radiative Properties of Opaque Materials. 4. Configuration Factors for Diffuse Surfaces with Uniform Radiosity. 5. Radiation Exchange in Enclosures Composed of Black and/or Diffuse–Gray Surfaces. 6. Exchange of Thermal Radiation among Nondiffuse Nongray Surfaces. 7. Radiation Combined with Conduction and Convection at Boundaries. 8. Electromagnetic Wave Theory. 9. Properties of Participating Media. 10. Absorption and Scattering by Particles and Agglomerates. 11. Fundamental Radiative Transfer Relations and Approximate Solution Methods. 12. Participating Media in Simple Geometries. 13. Numerical Solution Methods for Radiative Transfer in Participating Media. 14. The Monte Carlo Method. Conjugate Heat Transfer in Participating Media. 15. Near-Field Thermal Radiation. 16. Radiative Effects in Translucent Solids, Windows, and Coatings. 17. Inverse Problems in Radiative Transfer. 18. Applications of Radiation Energy Transfer. Appendix A: Conversion Factors, Radiation Constants, and Blackbody Functions. Appendix B: Radiative Properties. Appendix C: Catalog of Selected Configuration Factors. Appendix D: Exponential Integral Relations and Two-Dimensional Radiation Functions.
520			_aThe seventh edition of this classic text outlines the fundamental physical principles of thermal radiation, as well as analytical and numerical techniques for quantifying radiative transfer between surfaces and within participating media. The textbook includes newly expanded sections on surface properties, electromagnetic theory, scattering and absorption of particles, and near-field radiative transfer, and emphasizes the broader connections to thermodynamic principles. Sections on inverse analysis and Monte Carlo methods have been enhanced and updated to reflect current research developments, along with new material on manufacturing, renewable energy, climate change, building energy efficiency, and biomedical applications.
650			_aHeat _xRadiation and absorption _914224
650			_aHeat _xTransmission _914225
650			_aMaterials _xThermal properties _914226
856			_uhttps://doi.org/10.1201/9780429327308
942			_cBK