Searching for triplet superconductivity in the Quasi-One-Dimensional K2Cr3As3

Abstract

The superconducting state of the newly discovered superconductor K2Cr3As3 with a quasi-one-dimensional crystal structure (T c 6 K) has been investigated by using magnetization and muon-spin relaxation or rotation (μSR) measurements. Our analysis of the temperature dependence of the superfluid density obtained from the transverse field (TF) μSR measurements fit very well to an isotropic s-wave character for the superconducting gap. Furthermore a similarly good fit can also be obtained using a d-wave model with line nodes. Our zero-field μSR measurements do reveal very weak evidence of the spontaneous appearance of an internal magnetic field near the transition temperature, which might indicate that the superconducting state is not conventional. This observation suggests that the electrons are paired via unconventional channels such as spin fluctuations, as proposed on the basis of theoretical models of K2Cr3As3. Furthermore, from our TF μSR study the magnetic penetration depth λL, superconducting carrier density ns, and effective-mass enhancement m* have been estimated to be λL(0) = 454(4) nm, ns = 2.4×1027 carriers/m3, and m* = 1.75 me, respectively.