9 research outputs found
Giant thermoemf in multiterminal superconductor/normal metal mesoscopic structures
We considered a mesoscopic superconductor/normal metal (S/N) structure in
which the N reservoirs are maintained at different temperatures. It is shown
that in the absence of current between the N reservoirs a voltage difference
arises between the superconducting and normal conductors. The voltage
oscillates with increasing phase difference between the
superconductors, and its magnitude does not depend on the small parameter
Comment: Resubmited, some changes to Text and Figure
Influence of Supercurrents on Low-Temperature Thermopower in Mesoscopic N/S Structures
The thermopower of mesoscopic normal metal/superconductor structures has been
measured at low temperatures. Effect of supercurrent present in normal part of
the structure was studied in two cases: when it was created by applied external
magnetic field and when it was applied directly using extra superconducting
electrodes. Temperature and magnetic field dependencies of thermopower are
compared to the numerical simulations based on the quasiclassical theory of the
superconducting proximity effect.Comment: 21 pages, 12 figures. To be published in the proceedings of the ULTI
conference organized in Lammi, Finland (2006
Thermoelectric effects in superconducting proximity structures
Attaching a superconductor in good contact with a normal metal makes rise to
a proximity effect where the superconducting correlations leak into the normal
metal. An additional contact close to the first one makes it possible to carry
a supercurrent through the metal. Forcing this supercurrent flow along with an
additional quasiparticle current from one or many normal-metal reservoirs makes
rise to many interesting effects. The supercurrent can be used to tune the
local energy distribution function of the electrons. This mechanism also leads
to finite thermoelectric effects even in the presence of electron-hole
symmetry. Here we review these effects and discuss to which extent the existing
observations of thermoelectric effects in metallic samples can be explained
through the use of the dirty-limit quasiclassical theory.Comment: 14 pages, 10 figures. 374th WE-Heraus seminar: Spin physics of
superconducting heterostructures, Bad Honnef, 200
Electronic Transport in Hybrid Mesoscopic Structures: A Nonequilibrium Green Function Approach
We present a unified transport theory of hybrid structures, in which a
confined normal state () sample is sandwiched between two leads each of
which can be either a ferromagnet () or a superconductor () via tunnel
barriers. By introducing a four-dimensional Nambu-spinor space, a general
current formula is derived within the Keldysh nonequilibrium Green function
formalism, which can be applied to various kinds of hybrid mesoscopic systems
with strong correlations even in the nonequilibrium situation. Such a formula
is gauge invariant. We also demonstrate analytically for some quantities, such
as the difference between chemical potentials, superconductor order parameter
phases and ferromagnetic magnetization orientations, that only their relative
value appears explicitly in the current expression. When applied to specific
structures, the formula becomes of the Meir-Wingreen-type favoring strong
correlation effects, and reduces to the Landauer-B\"uttiker-type in
noninteracting systems such as the double-barrier resonant structures, which we
study in detail beyond the wide-band approximation.Comment: 24 pages, 12 eps figures, Revtex
Theory of phase-coherent transport in mesoscopic superconductors
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