4,641 research outputs found
Spin susceptibility in small Fermi energy systems: effects of nonmagnetic impurities
In small Fermi energy metals, disorder can deeply modify superconducting
state properties leading to a strong suppression of the critical temperature
. In this paper, we show that also normal state properties can be
seriously influenced by disorder when the Fermi energy is
sufficiently small. We calculate the normal state spin susceptibility
for a narrow band electron-phonon coupled metal as a function of the
non-magnetic impurity scattering rate . We find that as soon
as is comparable to , is strongly reduced
with respect to its value in the clean limit. The effects of the
electron-phonon interaction including the nonadiabatic corrections are
discussed. Our results strongly suggest that the recent finding on irradiated
MgB samples can be naturally explained in terms of small values
associated with the -bands of the boron plane, sustaining therefore the
hypothesis that MgB is a nonadiabatic metal.Comment: 7 pages, 6 eps figures, to appear on Eur. Phys. J.
The physical origin of the electron-phonon vertex correction
The electron-phonon vertex correction has a complex structure both in
momentum and frequency. We explain this structure on the basis of physical
considerations and we show how the vertex correction can be decomposed into two
terms with different physical origins. In particular, the first term describes
the lattice polarization induced by the electrons and it is essentially a
single-electron process whereas the second term is governed by the
particle-hole excitations due to the exchange part of the phonon-mediated
electron-electron interaction. We show that by weakening the influence of the
exchange interaction the vertex takes mostly positive values giving rise to an
enhanced effective coupling in the scattering with phonons. This weakening of
the exchange interaction can be obtained by lowering the density of the
electrons, or by considering only long-ranged (small q) electron-phonon
couplings. These findings permit to understand why in the High-Tc materials the
small carrier density and the long ranged electron-phonon interaction may play
a positive role in enhancing Tc.Comment: 11 pages, 5 postscript figure
s- and d-wave Symmetries in Nonadiabatic Theory of Superconductivity
High- superconductors have Fermi energies much smaller than
conventional metals comparable to phonon frequencies. In such a situation
nonadiabatic effects are important. A generalization of Eliashberg theory in
the nonadiabatic regime has previously been shown to reproduce some anomalous
features of the high- superconductors as for istance the enhancement of
or the isotopic effects on and . In this contribution we
address the issue of the symmetry of the gap in the context of nonadiabatic
superconductivity. We show that vertex corrections have a momentum structure
which favours d-wave superconductivity when forward scattering is predominant.
An additional increase of is also found.Comment: 6 pages, 3 eps figure, ijmpb-macros, proceeding of SATT10, to appear
on Int. Journ. Mod. Phys.
A survey of nonadiabatic superconductivity in cuprates and fullerides
High- superconductors are characterized by very low carrier densities.
This feature leads to two fundamental consequences: on one hand the Fermi
energies are correspondingly small and they can be of the same order of phonon
frequencies. In such a situation nonadiabatic corrections arising from the
breakdown of Migdal's theorem can not be longer neglected. In addition, small
carrier densities imply poor screening and correlation effects have to be taken
into account. We present a comprehensive overview of the theory of
superconductivity generalized into the nonadiabatic regime which is
qualitatively different from the conventional one. In this framework some of
the observed properties of the cuprates and the fullerene compounds can be
naturally accounted for, and a number of theoretical predictions are proposed
that can be experimentally tested.Comment: 1 eps figure, ijmpb-macros, proceeding of SATT10, to appear on Int.
Journ. Mod. Phys.
High superconductivity in MgB by nonadiabatic pairing
The evidence for the key role of the bands in the electronic
properties of MgB points to the possibility of nonadiabatic effects in the
superconductivity of these materials. These are governed by the small value of
the Fermi energy due to the vicinity of the hole doping level to the top of the
bands. We show that the nonadiabatic theory leads to a coherent
interpretation of K and the boron isotope coefficient without invoking very large couplings and it naturally explains the
role of the disorder on . It also leads to various specific predictions
for the properties of MgB and for the material optimization of these type
of compounds.Comment: 4 revtex pages, 3 eps figures, to appear on Phys. Rev. Let
Relevance of multiband Jahn-Teller effects on the electron-phonon interaction in C
Assessing the effective relevance of multiband effects in the fullerides is
of fundamental importance to understand the complex superconducting and
transport properties of these compounds. In this paper we investigate in
particular the role of the multiband effects on the electron-phonon (el-ph)
properties of the bands coupled with the Jahn-Teller intra-molecular
vibrational modes in the C compounds. We show that, assuming
perfect degeneracy of the electronic bands, vertex diagrams arising from the
breakdown of the adiabatic hypothesis, are one order of magnitude smaller than
the non-crossing terms usually retained in the Migdal-Eliashberg (ME) theory.
These results permit to understand the robustness on ME theory found by
numerical calculations. The effects of the non degeneracy of the in
realistic systems are also analyzed. Using a tight-binding model we show that
the el-ph interaction is mainly dominated by interband scattering within a
single electronic band. Our results question the reliability of a degenerate
band modeling and show the importance of these combined effects in the
C family.Comment: 5 pages, 3 eps figure
Anomalous impurity effects in nonadiabatic superconductors
We show that, in contrast with the usual electron-phonon Migdal-Eliashberg
theory, the critical temperature Tc of an isotropic s-wave nonadiabatic
superconductor is strongly reduced by the presence of diluted non-magnetic
impurities. Our results suggest that the recently observed Tc-suppression
driven by disorder in K3C60 [Phys. Rev. B vol.55, 3866 (1997)] and in
Nd(2-x)CexCuO(4-delta) [Phys. Rev. B vol.58, 8800 (1998)] could be explained in
terms of a nonadiabatic electron-phonon coupling. Moreover, we predict that the
isotope effect on Tc has an impurity dependence qualitatively different from
the one expected for anisotropic superconductors.Comment: 10 pages, euromacr.tex, europhys.sty, 6 figures. Replaced with
accepted version (Europhysics Letters
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