Giant Resonant Enhancement of Photoinduced Dynamical Cooper Pairing, far above Tc

Abstract

Pump-probe experiments performed on K3C60 have unveiled both optical and transport signatures of metastable light-induced superconductivity up to room temperature, far above Tc. Recent experiments have uncovered that excitation in the vicinity of 50 ~meV enables the observation of high temperature light-induced superconductivity at significantly lower fluences. Inspired by these experiments we develop a mechanism which can explain such a giant resonant enhancement of light-induced superconductivity. Within a minimal non-linear Holstein model, we show that resonantly driving optical Raman modes leads to a time-dependent electron-phonon coupling. Such a coupling then modulates the effective electron-electron attraction, with the strongest modulations occurring when the drive is resonant with the phonon frequency. These dynamical modulations of the pairing interactions lead to Floquet-BCS instabilities at temperatures far exceeding equilibrium Tc, as observed in experiments. We conclude by discussing the implications of our general analysis on the K3C60 experiments specifically and suggesting experimental signatures of our mechanism.