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ЖЭТФ, Том 127, Вып. 2, стр. 372 (Февраль 2005)
(Английский перевод - JETP, Vol. 100, No 2, p. 331, February 2005 доступен on-line на www.springer.com )

INTERACTION CORRECTIONS TO THERMAL TRANSPORT COEFFICIENTS IN DISORDERED METALS: THE QUANTUM KINETIC EQUATION APPROACH
Catelani G., Aleiner I.L.

Поступила в редакцию: 30 Августа 2004

PACS: 71.10.Ay, 72.10.Bg, 72.15.Eb

DJVU (458.3K) PDF (625.4K)

We consider the singular electron-electron interaction corrections to the transport coefficients in disordered metals to test the validity of the Wiedemann - Franz law. We develop a local, quantum kinetic equation approach in which the charge and energy conservation laws are explicitly satisfied. To obtain the local description, we introduce bosonic distribution functions for the neutral low-energy collective modes (electron-hole pairs). The resulting system of kinetic equations enables us to distinguish between the different physical processes involved in the charge and energy transport: the elastic electron scattering affects both, while the inelastic processes influence only the latter. Moreover, the neutral bosons, although incapable of transporting charge, contribute significantly to the energy transport. In our approach, we calculate on equal footing the electric and thermal conductivities and the specific heat in any dimension. We find that the Wiedemann - Franz law is always violated by the interaction corrections; the violation is larger for one- and two-dimensional systems in the diffusive regime T\tau \ll \hbar and is due to the energy transported by neutral bosons. For two-dimensional systems in the quasi-ballistic regime T\tau \gg \hbar, the inelastic scattering of the electron on the bosons also contributes to the violation.

 
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