397 research outputs found
Lower Critical Field Hc1(T) and Pairing Symmetry Based on Eilenberger Theory
We quantitatively estimate different T-dependences of Hc1 between s wave and
d wave pairings by Eilenberger theory. The T-dependences of Hc1(T) show
quantitative deviation from those in London theory. We also study differences
of Hc1(T) between p+ and p- wave pairing in chiral p wave superconductors.
There, Hc1(T) is lower in p- wave pairing, and shows the same T-dependence as
in s wave pairing.Comment: 2 pages, 1 figur
NMR relaxation time around a vortex in stripe superconductors
Site-dependent NMR relaxation time is calculated in the vortex
state using the Bogoliubov-de Gennes theory, taking account of possible
"field-induced stripe'' states in which the magnetism arises locally around a
vortex core in d-wave superconductivity. The recently observed huge enhancement
below at a core site in TlBaCuO is
explained. The field-induced stripe picture explains consistently other
relevant STM and neutron experiments.Comment: 4 pages, 4 figure
Comment on ``Quasiparticle Spectra around a Single Vortex in a d-wave Superconductor''
In a recent Letter Morita, Kohmoto and Maki analyzed the structure of
quasiparticle states near a single vortex in a d-wave superconductor using an
approximate version of the Bogoliubov - de Gennes theory. Their principal
result is the existence of a bound state within the core region at finite
energy with full rotational symmetry, which they assert explains the recent
scanning tunneling microscopy results on YBCO single crystals. Here we argue
that the approximation used in this work is fundamentally inadequate for the
description of a d-wave vortex and that the obtained circular symmetry of the
local density of states is an unphysical artifact of this approximation.Comment: 1 page REVTeX, to appear in PR
Magnetization process in a chiral p-wave superconductor with multi-domains
A simulation study for the magnetization process is performed for the
multi-domain state in a chiral p-wave superconductor, using the time-dependent
Ginzburg-Landau theory. The external field penetrates inside as core-less
vortices through the domain wall, forming the vortex sheet structure. We find
that, with increasing magnetic fields, the domain walls move so that the
unstable domains shrink to vanish. Therefore, the single domain structure is
realized at higher fields
Flux flow and pinning of the vortex sheet structure in a two-component superconductor
A simulation study using the time-dependent Ginzburg-Landau theory is
performed for the vortex state in two-component superconductors, such as
PrOs_4_Sb_12_. We investigate the flux flow and the pinning of the vortex sheet
structure. We find domain wall that traps half flux-quantum vortices and moves
with the flux flow. In the pinning case, we observe an emitting process of a
conventional vortex from the vortex sheet by combining a pair of half
flux-quantum vortices.Comment: 4 pages, 4 figures, to appear in Phys. Rev.
The effect of nonmagnetic impurities on the local density of states in s-wave superconductors
We study the effect of nonmagnetic impurities on the local density of states
(LDOS) in s-wave superconductors. The quasiclassical equations of
superconductivity are solved selfconsistently to show how LDOS evolves with
impurity concentration. The spatially averaged zero-energy LDOS is a linear
function of magnetic induction in low fields, N(E=0)=cB/H_{c2}, for all
impurity concentration. The constant of proportionality "c" depends weakly on
the electron mean free path. We present numerical data for differential
conductance and spatial profile of zero-energy LDOS which can help in
estimating the mean free path through the LDOS measurement.Comment: 7 pages, 7 figures (high quality color figure available on request
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