Muon-Spin Rotation Measurements of the Magnetic Field Dependence of the Vortex-Core Radius and Magnetic Penetration Depth in NbSe2

A. Wong (University of British Columbia); G.M. Luke (Columbia University); J. Chakhalian; J.E. Sonier; J.H. Brewer; J.W. Brill (University of Kentucky); R.F. Kiefl; R.I. Miller; S.R. Dunsiger; W.A. MacFarlane

arxiv: cond-mat/9708117 · v1 · submitted 1997-08-15 · ❄️ cond-mat.supr-con

Muon-Spin Rotation Measurements of the Magnetic Field Dependence of the Vortex-Core Radius and Magnetic Penetration Depth in NbSe2

J.E. Sonier , R.F. Kiefl , J.H. Brewer , J. Chakhalian , S.R. Dunsiger , W.A. MacFarlane , R.I. Miller , A. Wong (University of British Columbia)

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G.M. Luke (Columbia University) J.W. Brill (University of Kentucky)

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classification ❄️ cond-mat.supr-con

keywords magneticfieldradiusdepthmuon-spinnbse2penetrationrotation

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Muon-spin rotation spectroscopy has been used to measure the internal magnetic field distribution in NbSe2 for Hc1 << H < 0.25 Hc2. The deduced profiles of the supercurrent density indicate that the vortex-core radius in the bulk decreases sharply with increasing magnetic field. This effect, which is attributed to increased vortex-vortex interactions, does not agree with the dirty-limit microscopic theory. A simple phenomenological equation in which the core radius depends on the intervortex spacing is used to model this behaviour. In addition, we find for the first time that the in-plane magnetic penetration depth increases linearly with H in the vortex state of a conventional superconductor.

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Muon-Spin Rotation Measurements of the Magnetic Field Dependence of the Vortex-Core Radius and Magnetic Penetration Depth in NbSe2

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