BCS quantum critical phenomena

Abstract

Theoretically, we recently showed that the scaling relation between the transition temperature Tc and the superfluid density at zero temperature ns (0) might exhibit a parabolic pattern [Scientific Reports 6 (2016) 23863]. It is significantly different from the linear scaling described by Homes' law, which is well known as a mean-field result. More recently, Bozovic et al. have observed such a parabolic scaling in the overdoped copper oxides with a sufficiently low transition temperature Tc [Nature 536 (2016) 309-311]. They further point out that this experimental finding is incompatible with the standard Bardeen-Cooper-Schrieffer (BCS) description. Here we report that if Tc is sufficiently low, applying the renormalization group approach into the BCS action at zero temperature will naturally lead to the parabolic scaling. Our result indicates that when Tc sufficiently approaches zero, quantum fluctuations will be overwhelmingly amplified so that the mean-field approximation may break down at zero temperature.