Nernst effect
Thermoelectric effect |
---|
This article needs additional citations for verification. (April 2024) |
In physics and chemistry, the Nernst effect (also termed the first Nernst–Ettingshausen effect, after Walther Nernst and Albert von Ettingshausen) is a thermoelectric (or thermomagnetic) phenomenon observed when a sample allowing electrical conduction is subjected to a magnetic field and a temperature gradient normal (perpendicular) to each other. An electric field will be induced normal to both.
This effect is quantified by the Nernst coefficient , which is defined to be
where is the y-component of the electric field that results from the magnetic field's z-component and the x-component of the temperature gradient .
The reverse process is known as the Ettingshausen effect and also as the second Nernst–Ettingshausen effect.
Physical picture
[edit]Mobile energy carriers (for example conduction-band electrons in a semiconductor) will move along temperature gradients due to statistics[dubious – discuss] and the relationship between temperature and kinetic energy. If there is a magnetic field transversal to the temperature gradient and the carriers are electrically charged, they experience a force perpendicular to their direction of motion (also the direction of the temperature gradient) and to the magnetic field. Thus, a perpendicular electric field is induced.
Sample types
[edit]The semiconductors exhibit the Nernst effect, as first observed by T. V. Krylova and Mochan in the Soviet Union in 1955.[1][non-primary source needed] In metals however, it is almost non-existent.[citation needed]
Superconductors
[edit]Nernst effect appears in the vortex phase of type-II superconductors due to vortex motion.[2][3][4] High-temperature superconductors exhibit the Nernst effect both in the superconducting and in the pseudogap phase.[5] Heavy fermion superconductors can show a strong Nernst signal which is likely not due to the vortices.[6]
See also
[edit]References
[edit]- ^ Krylova, T. V.; Mochan, I. V. (1955). "Investigation of the Nernst effect of germanium". J. Tech. Phys. 25 (12): 2119–2121.
- ^ Huebener, R. P.; Seher, A. (1969-05-10). "Nernst Effect and Flux Flow in Superconductors. I. Niobium". Physical Review. 181 (2): 701–709. Bibcode:1969PhRv..181..701H. doi:10.1103/PhysRev.181.701. ISSN 0031-899X.
- ^ Huebener, R. P.; Seher, A. (1969-05-10). "Nernst Effect and Flux Flow in Superconductors. II. Lead Films". Physical Review. 181 (2): 710–716. Bibcode:1969PhRv..181..710H. doi:10.1103/PhysRev.181.710. ISSN 0031-899X.
- ^ Rowe, V. A.; Huebener, R. P. (1969-09-10). "Nernst Effect and Flux Flow in Superconductors. III. Films of Tin and Indium". Physical Review. 185 (2): 666–671. Bibcode:1969PhRv..185..666R. doi:10.1103/PhysRev.185.666. ISSN 0031-899X.
- ^ Xu, Z. A.; Ong, N. P.; Wang, Y.; Kakeshita, T.; Uchida, S. (2000-08-03). "Vortex-like excitations and the onset of superconducting phase fluctuation in underdoped La2-xSrxCuO4". Nature. 406 (6795): 486–488. doi:10.1038/35020016. ISSN 0028-0836. PMID 10952303.
- ^ Bel, R.; Behnia, K.; Nakajima, Y.; Izawa, K.; Matsuda, Y.; Shishido, H.; Settai, R.; Onuki, Y. (2004-05-27). "Giant Nernst Effect in ${\mathrm{CeCoIn}}_{5}$". Physical Review Letters. 92 (21): 217002. arXiv:cond-mat/0311473. doi:10.1103/PhysRevLett.92.217002. PMID 15245310.