Influence of pressure on properties of multi-gap type-I superconductor BeAu

Abstract

We report on studies of the superconducting and normal state properties of the noncentrosymmetric superconductor BeAu under hydrostatic pressure conditions. The room-temperature equation of state (EOS) reveals the values of the bulk modulus (B0) and its first derivative (B0) at ambient pressure to be B0 132~GPa and B0 30, respectively. Up to the highest pressures studied (p 2.2~GPa), BeAu remains a multi-gap type-I superconductor. The analysis of B c(T, p) data within the self-consistent two-gap approach suggests the presence of two superconducting energy gaps, with the gap-to-T c ratios 1/k BT c 2.3 and 2/k BT c 1.1 for the larger and smaller gaps, respectively [ = (0) is the zero-temperature value of the gap and k B is the Boltzmann constant]. With increasing pressure, 1/k BT c increases while 2/k BT c decreases, suggesting that pressure enhances (weakens) the coupling strength between the superconducting carriers within the bands where the larger (smaller) superconducting energy gap has opened. The superconducting transition temperature T c, blackthe zero-temperature values of the superconducting gaps 1 and 2 and the zero-temperature value of the thermodynamic critical field B c(0) decrease with increasing pressure, with the rates of dT c/ dp -0.195~K/GPa, black d1/ dp -0.034~meV/GPa, d2/ dp -0.029~meV/GPa, and dB c(0)/ dp = -2.65(1)~mT/GPa, respectively. The measured B c(0) values plotted as a function of T c follow an empirical scaling relation established for conventional type-I superconductors.

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