J. E. Sonier scite author profile

The thermal conductivity kappa of the layered s-wave superconductor NbSe2 was measured down to T(c)/100 throughout the vortex state. With increasing field, we identify two regimes: one with localized states at fields very near H(c1) and one with highly delocalized quasiparticle excitations at higher fields. The two associated length scales are naturally explained as multiband superconductivity, with distinct small and large superconducting gaps on different sheets of the Fermi surface. This behavior is compared to that of the multiband superconductor MgB2 and the conventional superconductor V3Si.

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Field Induced Reduction of the Low-Temperature Superfluid Density inYBa2Cu3O6.95
Sonier
¹
,
Brewer
²
,
Kiefl
³

et al. 1999
Phys. Rev. Lett.
104
19
116
2
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A novel high magnetic field (8 T) spectrometer for muon spin rotation (µSR) has been used to measure the temperature dependence of the in-plane magnetic penetration depth λ ab in YBa2Cu3O6.95. At low H and low T , λ ab exhibits the characteristic linear T -dependence associated with the energy gap of a d x 2 −y 2 -wave superconductor. However, at higher fields λ ab is essentially temperature independent at low T . We discuss possible interpretations of this surprising new feature in the low-energy excitation spectrum. 74.25.Nf, 74.72.Bk, 76.75.+i In a superconductor, the resistance to the flow of electric current drops to an unmeasurably small value below a certain critical temperature T c . This remarkable characteristic is due to the formation of pairs of electrons (or holes), called "Cooper pairs", which link together and carry the charge through the sample with virtually no opposition. To break apart the pairs, an additional energy is needed to excite individual electrons above an energy gap which exists at the Fermi surface in the superconducting state. The nature of these elementary excitations, known as "quasiparticles" (QPs), is directly related to the size and symmetry of the energy gap. The gap itself reflects the symmetry of the pair wave function (or order parameter), knowledge of which is essential to understanding the physics of the underlying mechanism responsible for superconductivity.A major breakthrough in the study of high-T c cuprate superconductors (HTSCs) came when it was realized that the symmetry of the energy gap was different from that in conventional low-T c materials. In particular, the energy gap was found to vanish along certain directions in momentum space. These so-called "nodes" serve as a conduit for extreme low-energy QP excitations. One of the key early experiments providing evidence for the existence of gap nodes was microwave measurements by Hardy et al.[1] of the in-plane penetration depth change ∆λ ab = λ ab (T )−λ ab (1.35 K) in the Meissner state of highpurity YBa 2 Cu 3 O 6.95 . In this phase, magnetic field is partially screened from the interior by "supercurrents" circulating around the sample perimeter. These supercurrents constitute the response of the superconductor to the applied field. The penetration depth λ is the characteristic length scale over which the field decays in from the surface, and the quantity λ −2 is proportional to the density of Cooper pairs, i.e. "superfluid density", n s . Because thermal energy can excite QPs, λ −2 decreases with increasing T . In a conventional superconductor, this temperature dependence is typically weak at low T because the isotropic energy gap exponentially cuts off the QP excitations as T → 0 K. In Ref.[1], however, λ −2 ab was found to decrease sharply upon raising the temperature above 1.35 K-the lowest temperature reached in the experiment. This suggested that the minimum gap size was very small. Moreover, at low temperatures ∆λ ab was observed to be proportional to T , which is characteristic of a superconducting o...

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J. E. Sonier

μSR studies of the vortex state in type-II superconductors

Heat Conduction in the Vortex State ofNbSe2: Evidence for Multiband Superconductivity

Field Induced Reduction of the Low-Temperature Superfluid Density inYBa2Cu3O6.95
Sonier
¹
,
Brewer
²
,
Kiefl
³

et al. 1999
Phys. Rev. Lett.
104
19
116
2
View full text Add to dashboard Cite

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About

J. E. Sonier

μSR studies of the vortex state in type-II superconductors

Heat Conduction in the Vortex State ofNbSe2: Evidence for Multiband Superconductivity

Field Induced Reduction of the Low-Temperature Superfluid Density inYBa2Cu3O6.95Sonier1, Brewer2, Kiefl3 et al. 1999Phys. Rev. Lett.104191162View full textAdd to dashboardCite

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Field Induced Reduction of the Low-Temperature Superfluid Density inYBa2Cu3O6.95
Sonier
¹
,
Brewer
²
,
Kiefl
³

et al. 1999
Phys. Rev. Lett.
104
19
116
2
View full text Add to dashboard Cite