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This book describes the theory of thermoelectric effects, both from a practical and a fundamental perspective, and presents many examples of applications of the theory to real materials.
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This book describes the theory of thermoelectric effects, both from a practical and a fundamental perspective, and presents many examples of applications of the theory to real materials.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Hurst & Co.
- Seitenzahl: 302
- Erscheinungstermin: 22. Juli 2014
- Englisch
- Abmessung: 254mm x 179mm x 20mm
- Gewicht: 713g
- ISBN-13: 9780198705413
- ISBN-10: 0198705417
- Artikelnr.: 40497540
- Verlag: Hurst & Co.
- Seitenzahl: 302
- Erscheinungstermin: 22. Juli 2014
- Englisch
- Abmessung: 254mm x 179mm x 20mm
- Gewicht: 713g
- ISBN-13: 9780198705413
- ISBN-10: 0198705417
- Artikelnr.: 40497540
Born in 1945, Veljko Zlatic studied physics in Zagreb and obtained his first degree from Zagreb University in 1969. From 1970 to 1974 he studied theoretical physics at Imperial College and obtained his PhD. He taught many body physics at Zagreb University from 1974 to 1999. He was Humboldt Fellow at Frankfurt University in 1980/81 and Berlin University in 1989, Visiting Fellow at Oxford University in 1993/1994, and Visiting Professor at Georgetown University 1996/97 and 2006/07. He retired as a Senior Scientist from the Institute of Physics in 2010. His main research interest is the theoretical description of strongly correlated materials. Born in 1946, René Monnier obtained his Diploma in Physics with honours from the University of Neuchâtel in 1970. He was a Visiting Fellow at Cornell University from January 1971 to July 1972, after which he returned to Neuchâtel, where he defended his thesis in April 1974. From October 1975 to July 1977 he was a postdoctoral fellow at Nordita, in Copenhagen. He joined ETH in October 1977 and was awarded the Professor title in 2000. His field of research is condensed matter theory, and his main interests lie in the study of the electronic structure and properties of random alloys and their surfaces, exotic compounds and strongly correlated systems. He has taught graduate courses on these subjects as well as introductory physics to students in engineering and in the life sciences.
* Introduction
* Part I: Classical theory
* 1: Phenomenological description of thermoelectric phenomena
* 2: Phenomenological transport equations
* 3: Physical interpretation
* 4: Thermomagnetic and galvanomagnetic effects
* 5: Solutions of the transport equations for homogenous
thermoelectrics
* 6: Solutions of the transport equations for inhomogeneous
thermoelectrics
* 7: Onsager's reciprocal relations in irreversible processes
* Part II: Quantum theory
* 8: Microscopic description of thermoelectric phenomena
* 9: Calculation of the response to an applied field
* 10: Current density operators for continuous models
* 11: Current density operators for lattice models
* 12: Jonson-Mahan theorem
* Part III: Comparison of theory and experiment
* 13: Kondo effect in dilute alloys
* 14: Rare earth intermetallics: heavy fermions and valence fluctuators
* 15: First principles approaches
* Appendix A: Single impurity models
* Appendix B: Green's functions
* Appendix C: Derivation of the spectral representation for the single
particle
* Appendix D: Dynamical Mean Field Theory of the PAM
* Appendix E: Scaling
* Appendix F: Transport properties of dilute alloys
* Appendix G: Spectral function in the non-crossing approximation (NCA)
* Appendix H: Correlation functions in the Fermi liquid regime
* Appendix I: Sommerfeld expansion for heavy fermion systems in the
DMFT approximation to the periodic Anderson model.
* Part I: Classical theory
* 1: Phenomenological description of thermoelectric phenomena
* 2: Phenomenological transport equations
* 3: Physical interpretation
* 4: Thermomagnetic and galvanomagnetic effects
* 5: Solutions of the transport equations for homogenous
thermoelectrics
* 6: Solutions of the transport equations for inhomogeneous
thermoelectrics
* 7: Onsager's reciprocal relations in irreversible processes
* Part II: Quantum theory
* 8: Microscopic description of thermoelectric phenomena
* 9: Calculation of the response to an applied field
* 10: Current density operators for continuous models
* 11: Current density operators for lattice models
* 12: Jonson-Mahan theorem
* Part III: Comparison of theory and experiment
* 13: Kondo effect in dilute alloys
* 14: Rare earth intermetallics: heavy fermions and valence fluctuators
* 15: First principles approaches
* Appendix A: Single impurity models
* Appendix B: Green's functions
* Appendix C: Derivation of the spectral representation for the single
particle
* Appendix D: Dynamical Mean Field Theory of the PAM
* Appendix E: Scaling
* Appendix F: Transport properties of dilute alloys
* Appendix G: Spectral function in the non-crossing approximation (NCA)
* Appendix H: Correlation functions in the Fermi liquid regime
* Appendix I: Sommerfeld expansion for heavy fermion systems in the
DMFT approximation to the periodic Anderson model.
* Introduction
* Part I: Classical theory
* 1: Phenomenological description of thermoelectric phenomena
* 2: Phenomenological transport equations
* 3: Physical interpretation
* 4: Thermomagnetic and galvanomagnetic effects
* 5: Solutions of the transport equations for homogenous
thermoelectrics
* 6: Solutions of the transport equations for inhomogeneous
thermoelectrics
* 7: Onsager's reciprocal relations in irreversible processes
* Part II: Quantum theory
* 8: Microscopic description of thermoelectric phenomena
* 9: Calculation of the response to an applied field
* 10: Current density operators for continuous models
* 11: Current density operators for lattice models
* 12: Jonson-Mahan theorem
* Part III: Comparison of theory and experiment
* 13: Kondo effect in dilute alloys
* 14: Rare earth intermetallics: heavy fermions and valence fluctuators
* 15: First principles approaches
* Appendix A: Single impurity models
* Appendix B: Green's functions
* Appendix C: Derivation of the spectral representation for the single
particle
* Appendix D: Dynamical Mean Field Theory of the PAM
* Appendix E: Scaling
* Appendix F: Transport properties of dilute alloys
* Appendix G: Spectral function in the non-crossing approximation (NCA)
* Appendix H: Correlation functions in the Fermi liquid regime
* Appendix I: Sommerfeld expansion for heavy fermion systems in the
DMFT approximation to the periodic Anderson model.
* Part I: Classical theory
* 1: Phenomenological description of thermoelectric phenomena
* 2: Phenomenological transport equations
* 3: Physical interpretation
* 4: Thermomagnetic and galvanomagnetic effects
* 5: Solutions of the transport equations for homogenous
thermoelectrics
* 6: Solutions of the transport equations for inhomogeneous
thermoelectrics
* 7: Onsager's reciprocal relations in irreversible processes
* Part II: Quantum theory
* 8: Microscopic description of thermoelectric phenomena
* 9: Calculation of the response to an applied field
* 10: Current density operators for continuous models
* 11: Current density operators for lattice models
* 12: Jonson-Mahan theorem
* Part III: Comparison of theory and experiment
* 13: Kondo effect in dilute alloys
* 14: Rare earth intermetallics: heavy fermions and valence fluctuators
* 15: First principles approaches
* Appendix A: Single impurity models
* Appendix B: Green's functions
* Appendix C: Derivation of the spectral representation for the single
particle
* Appendix D: Dynamical Mean Field Theory of the PAM
* Appendix E: Scaling
* Appendix F: Transport properties of dilute alloys
* Appendix G: Spectral function in the non-crossing approximation (NCA)
* Appendix H: Correlation functions in the Fermi liquid regime
* Appendix I: Sommerfeld expansion for heavy fermion systems in the
DMFT approximation to the periodic Anderson model.