Glass-induced enhancement of superconducting Tc: Pairing via dissipative mediators

Abstract

With substantial evidence of glassy behavior in the phase diagram of high Tc superconductors and its co-existence with superconductivity, we attempt to answer the question: what are the properties of a superconducting state where the force driving cooper pairing becomes dissipative? We find that when the bosonic mediator is local, dissipation acts to reduce the superconducting critical temperature (Tc). On the other hand, contrary to na\"ive expectations, Tc behaves non-monotonically with dissipation for a non-local mediator -- weakly dissipative bosons at different energy scales act coherently to give rise to an increase in Tc and eventually destroy superconductivity when the dissipation exceeds a critical value. The critical value occurs when dissipative effects become comparable to the energy scale associated with the spatial stiffness of the mediator, at which point, Tc acquires a maximum. We outline consequences of our results to recent proton irradiation experiments (M. Leroux et al.,~Welp2018) on the cuprate superconductor La2-xBaxCuO4 (LBCO) which observe a disorder induced increase in Tc even when the transition temperature of the proximate charge density wave (CDW) is unaffected by the presence of irradiation. Our mechanism is a novel way to raise Tc that does not require a `tug-of-war' -type scenario between two competing phases.