Experimental consequences of pz-wave spin triplet superconductivity in A2Cr3As3

Abstract

The experimental observable properties of the triplet pz-wave pairing state, proposed by Wu et al. [arXiv:1503.06707] in quasi-one dimensional A2Cr3As3 materials, are theoretically investigated. This pairing state is characterized by the line nodes on the kz=0 plane on the Fermi surfaces. Based on the three-band tight binding model, we obtain the specific heat, superfluid density, Knight shift and spin relaxation rate and find that all these properties at low temperature (T Tc) show powerlaw behaviors and are consistent available experiments. Particularly, the superfluid density determined by the pz-wave pairing state in this quasi-one dimensional system is anisotropic: the in-plane superfluid density varies as T but the out-plane one varies as T3 at low temperature. The anisotropic upper critical field reported in experiment is consistent with the Sz=0 (i.e., (+)) pz-wave pairing state. We also suggest the phase-sensitive dc-SQUID measurements to pin down the triplet pz-wave pairing state.