Nonvolatile optical control of interlayer stacking order in 1T-TaS2

TL;DR

This study demonstrates the all-optical, nonvolatile control of interlayer stacking in 1T-TaS2, revealing a reversible phase transition driven by ultrafast laser pulses and coherent phonons, with implications for future optoelectronic devices.

Contribution

It uncovers the mechanism of laser-induced hidden states in 1T-TaS2 and shows how coherent phonons control reversible stacking order transitions.

Findings

Reversible transition involves a mixed-stacking state with low-energy interlayer orders.

Ultrafast formation of hidden state is initiated by a coherent phonon.

Recovery involves domain coarsening and is controllable via pulse sequences.

Abstract

Nonvolatile optical manipulation of material properties on demand is a highly sought-after feature in the advancement of future optoelectronic applications. While the discovery of such metastable transition in various materials holds good promise for achieving this goal, their practical implementation is still in the nascent stage. Here, we unravel the nature of the ultrafast laser-induced hidden state in 1T-TaS2 by systematically characterizing the electronic structure evolution throughout the reversible transition cycle. We identify it as a mixed-stacking state involving two similarly low-energy interlayer orders, which is manifested as the charge density wave phase disruption. Furthermore, our comparative experiments utilizing the single-pulse writing, pulse-train erasing and pulse-pair control explicitly reveal the distinct mechanism of the bidirectional transformations -- the ultrafast formation of the hidden state is initiated by a coherent phonon which triggers a competition of interlayer stacking orders, while its recovery to the initial state is governed by the progressive domain coarsening. Our work highlights the deterministic role of the competing interlayer orders in the nonvolatile phase transition in the layered material 1T-TaS2, and promises the coherent control of the phase transition and switching speed. More importantly, these results establish all-optical engineering of stacking orders in low-dimensional materials as a viable strategy for achieving desirable nonvolatile electronic devices.