Thermal and electrical currents in nanoscale electronic interferometers


Autoria(s): Cho, S. Y.; McKenzie, R. H.
Contribuinte(s)

P. D. Adams

Data(s)

01/01/2005

Resumo

We theoretically study thermal transport in an electronic interferometer comprising a parallel circuit of two quantum dots, each of which has a tunable single electronic state which are connected to two leads at different temperature. As a result of quantum interference, the heat current through one of the dots is in the opposite direction to the temperature gradient. An excess heat current flows through the other dot. Although locally, heat flows from cold to hot, globally the second law of thermodynamics is not violated because the entropy current associated with heat transfer through the whole device is still positive. The temperature gradient also induces a circulating electrical current, which makes the interferometer magnetically polarized.

Identificador

http://espace.library.uq.edu.au/view/UQ:76338/UQ76338.pdf

http://espace.library.uq.edu.au/view/UQ:76338

Idioma(s)

eng

Publicador

American Physical Society

Palavras-Chave #Physics, Condensed Matter #Quantum-dot #Landauer Formula #Thermopower #Transport #Interference #C1 #240202 Condensed Matter Physics - Structural Properties #780102 Physical sciences
Tipo

Journal Article