Superfluid density and superconducting gaps of RbFe2As2 as a function of hydrostatic pressure

Abstract

The superfluid density and superconducting gaps of superconducting RbFe2As2 have been determined as a function of temperature, magnetic field and hydrostatic pressure by susceptibility and muon-spin spectroscopy measurements. From the data, fundamental microscopic parameters of the superconducting state like the London penetration depth λ, the gap values , the upper critical field Bc2, and the Ginzburg-Landau parameter have been obtained. In accordance with earlier measurements the ratio of the superfluid density ns λ-2 to the superconducting transition temperature Tc=2.52(2) K at ambient pressure is found to be much larger in the strongly hole-overdoped RbFe2As2 than in high-Tc Fe-based and other unconventional superconductors. As a function of pressure Tc strongly decreases with a rate of dTc/dp = -1.32 K/GPa, i.e. it is reduced by 52 % at p = 1 GPa. The temperature dependence of ns is best described by a two gap s-wave model with both superconducting gaps being decreased by hydrostatic pressure until smaller gap completely disappears at p = 1 GPa.