Conventional superconductivity and hysteretic Campbell penetration depth in single crystals MgCNi3

Abstract

Single crystals of MgCNi3, with areas sized up to 1 mm2, were grown by the self flux method using a cubic anvil high pressure technique. The first critical field Hc1, determined from a zero temperature extrapolation, is around 18 mT. Using the tunnel - diode resonator technique, the London penetration depth was measured with no applied dc field and the Campbell penetration depth was measured with the external dc fields up to 9T for two different sample orientations with respect to the direction of applied magnetic field. The absolute value of the London penetration depth, λ(0) = 245 10 nm was determined from the thermodynamic Rutgers formula. The superfluid density, s=(λ(0)/λ(T))2 was found to follow the clean isotropic s-wave behavior predicted by the weak - coupling BCS theory in the whole temperature range. The low - temperature behavior of the London penetration depth fits the BCS analytic form as well and produces close to the weak - coupling value of (0)/kBTc = 1.71. The temperature dependence of the upper critical field, Hc2, was found to be isotropic with a slope at Tc of -2.63 T/K and Hc2(0) ≈ 12.3 T at zero temperature. The Campbell penetration depth probes the vortex lattice response in the mixed state and is sensitive to the details of the pinning potential. For MgCNi3, an irreversible feature has been observed in the TDR response when the sample is field-cooled and warmed versus zero-field-cooled and warmed. This feature possesses a non-monotonic field dependence and has commonly been referred to as the peak effect and is most likely related to a field - dependent non - parabolic pinning potential.