
In recent years, there have been important developments in the design and fabrication of new thermoelectrics. While a decade ago, progress was mainly empirical, recent advances in theoretical methods have led to a deeper understanding of the parameters that affect the performance of materials in thermoelectric devices. These have brought the goal of producing materials with the required characteristics for commercial application a significant step closer. A search for efficient materials requires a fully microscopic treatment of the charge and heat transport, and the aim of this book is to explain all thermoelectric phenomena from this modern quantum-mechanical perspective. In the first part on phenomenology, conjugate current densities and forces are derived from the condition that the rate of change of the entropy density of the system in the steady state is given by the scalar product between them. The corresponding transport coefficients are explicitly shown to satisfy Onsager's reciprocal relations. The transport equations are solved for a number of cases, and the coefficient of performance, the efficiency, and the figure of merit are computed. State-of-the-art methods for the solution of the transport equations in inhomogeneous thermoelectrics are presented. A brief account on how to include magnetization transport in the formalism is also given. In the second part, quantum mechanical expressions for the transport coefficients are derived, following the approach by Luttinger. These are shown to satisfy Onsager's relations by construction. Three lattice models, currently used to describe strongly correlated electron systems, are introduced: the Hubbard, the Falicov-Kimball, and the periodic Anderson model (PAM), and the relevant current density operators are derived for each of them. A proof of the Jonson-Mahan theorem, according to which all transport coefficients for these models can be obtained from the integral of a unique transport function multiplied by d
This text investigates the microscopic mechanisms governing charge and heat transport to provide a comprehensive quantum-mechanical framework for understanding thermoelectric phenomena. René Monnier and Veljko Zlatic utilize their expertise in condensed matter physics to bridge the gap between empirical material development and theoretical rigor. By applying the Luttinger approach and analyzing specific lattice models, the authors establish a formal basis for calculating transport coefficients in modern thermoelectric devices.
What You Will Find
Scope Limits
Experts recognize this work as a rigorous technical resource for researchers and graduate students specializing in strongly correlated electron systems. Readers frequently note the high mathematical density of the prose, which serves as a foundational reference for those seeking to understand the theoretical underpinnings of thermoelectric efficiency.
Page Count:
304
Publication Date:
2014-01-01
Publisher:
OUP Oxford
ISBN-10:
0191015407
ISBN-13:
9780191015403
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