Coherent control of a structural phase transition in a solid-state surface system

TL;DR

This paper demonstrates that coherent vibrational control can actively manipulate a metal-insulator phase transition in a solid-state surface system using optical pulses, highlighting the role of vibrational coherence in ultrafast structural changes.

Contribution

It introduces a method for mode-selective coherent control of a phase transition in a solid surface system using double-pulse excitation and ultrafast diffraction techniques.

Findings

Strong oscillations in switching efficiency depend on pulse delay

Vibrational coherence influences transition dynamics

Structural modes govern the phase transition on femtosecond timescales

Abstract

The desire to exert active optical control over matter is a unifying theme across multiple scientific disciplines, as exemplified by all-optical magnetic switching, light-induced metastable or exotic phases of solids and the coherent control of chemical reactions. Typically, these approaches dynamically steer a system towards states or reaction products far from equilibrium. In solids, metal-insulator transitions are an important target for optical manipulation, offering dramatic and ultrafast changes of the electronic and lattice properties. In this context, essential questions concern the role of coherence in the efficiencies and thresholds of such transitions. Here, we demonstrate coherent vibrational control over a metal-insulator structural phase transition in a quasi-one-dimensional solid-state surface system. An optical double-pulse excitation scheme is used to drive the system from the insulating to a metastable metallic state, and the corresponding structural changes are monitored by ultrafast low-energy electron diffraction. We observe strong oscillations in the switching efficiency as a function of the double-pulse delay, revealing the importance of vibrational coherence in two key structural modes governing the transition on a femtosecond timescale. This mode-selective coherent control of solids and surfaces could open new routes to switching chemical and physical functionalities, facilitated by metastable and non-equilibrium states.