Logarithmic Upturn in Low-Temperature Electronic Transport as a Signature of d-Wave Order in Cuprate Superconductors

Abstract

In cuprate superconductors, high magnetic fields have been used extensively to suppress superconductivity and expose the underlying normal state. Early measurements revealed insulating-like behavior in underdoped material versus temperature T, in which resistivity increases on cooling with a puzzling (1/T) form. We instead use microwave measurements of flux-flow resistivity in YBa2Cu3O6+y and Tl2Ba2CuO6+δ to study charge transport deep inside the superconducting phase, in the low temperature and low field regime. Here, the transition from metallic low-temperature resistivity (d/dT>0) to a (1/T) upturn persists throughout the superconducting doping range, including a regime at high carrier dopings in which the field-revealed normal-state resistivity is Fermi-liquid-like. The (1/T) form is thus likely a signature of d-wave superconducting order, and the field-revealed normal state's (1/T) resistivity may indicate the free-flux-flow regime of a phase-disordered d-wave superconductor.