Discovery of Light-induced Metastable Martensitic Anomaly Controlled by Single-Cycle Terahertz Pulses

Abstract

We report on an ultrafast photoinduced phase transition with a strikingly long-lived Martensitic anomaly driven by above-threshold single-cycle terahertz (THz) pulses in Nb3Sn. A non-thermal, THz-induced depletion of low frequency conductivity indicates increased gap splitting of high energy 12 bands by removal of their degeneracies which enhances the Martensitic phase. In contrast, optical pumping leads to a 12 gap melting. Such light-induced non-equilibrium Martensitic instability persists up to a critical temperature 100 K, i.e., more than twice the equilibrium temperature, and can be stabilized beyond technologically-relevant, nanosecond timescales. Together with first-principle simulations, we identify a compelling THz tuning of structural fluctuations via Eu phonons to achieve a non-equilibrium ordering at high temperatures far exceeding those for equilibrium states.