Ultrafast Stiffening of the Lattice Potential and Metastable State Formation in 1T-TiSe2

Abstract

We use ultrafast optical spectroscopy to investigate the electronic and lattice dynamics of the charge-density wave (CDW) material 1T-TiSe2 across various temperatures and pump fluences. We reveal a close relationship between the observed ultrafast dynamical processes and two characteristic temperatures: T CDW (202 K) and T* (165 K). Two coherent phonon modes are identified: a high-frequency A1g mode (ω1) and a lower-frequency A1g CDW amplitude mode (ω2). In stark contrast to thermal melting, where phonons soften, the CDW amplitude mode exhibits anomalous hardening (frequency upshift) with increasing pump fluence. We establish this hardening as the direct signature of an ultrafast restoration of the bare lattice potential. The photoexcited carrier plasma screens the long-range electron-phonon interactions that drive the Peierls-like instability, effectively ``undressing" the soft phonon and driving its frequency toward the stiffer value of the unrenormalized lattice. Furthermore, an abrupt increase in the excited state buildup time above a critical pump fluence marks a sharp boundary to a photoinduced metastable metallic state. These findings demonstrate that the CDW order in 1T-TiSe2 is governed by a fragile, fluence-tunable competition between excitonic correlations and lattice dynamics.