Effects of Floquet Engineering on the Coherent Exciton Dynamics in Monolayer WS$_2$

TL;DR

This study uses multidimensional coherent spectroscopy to investigate how ultrafast Floquet engineering affects exciton coherence in monolayer WS$_2$, revealing phase control, non-adiabatic effects, and decoherence mechanisms relevant for quantum manipulation.

Contribution

It provides the first direct measurement of coherent exciton dynamics under ultrafast Floquet driving in monolayer WS$_2$, highlighting non-adiabatic effects and decoherence sources.

Findings

Phase rotations during 100 fs pulses exceed π.

AC-Stark and Bloch-Siegert shifts explain phase behavior.

Power broadening causes additional decoherence.

Abstract

Coherent optical manipulation of electronic bandstructures via Floquet Engineering is a promising means to control quantum systems on an ultrafast timescale. However, the ultrafast switching on/off of the driving field comes with questions regarding the limits of validity of the Floquet formalism, which is defined for an infinite periodic drive, and to what extent the transient changes can be driven adibatically. Experimentally addressing these questions has been difficult, in large part due to the absence of an established technique to measure coherent dynamics through the duration of the pulse. Here, using multidimensional coherent spectroscopy we explicitly excite, control, and probe a coherent superposition of excitons in the $K$ and $K^\prime$ valleys in monolayer WS$_2$. With a circularly polarized, red-detuned, pump pulse, the degeneracy of the $K$ and $K^\prime$ excitons can be lifted and the phase of the coherence rotated. We demonstrate phase rotations during the 100 fs driving pulse that exceed $\pi$, and show that this can be described by a combination of the AC-Stark shift of excitons in one valley and Bloch-Siegert shift of excitons in the opposite valley. Despite showing a smooth evolution of the phase that directly follows the intensity envelope of the pump pulse, the process is not perfectly adiabatic. By measuring the magnitude of the macroscopic coherence as it evolves before, during, and after the pump pulse we show that there is additional decoherence caused by power broadening in the presence of the pump. This non-adiabaticity may be a problem for many applications, such as manipulating q-bits in quantum information processing, however these measurements also suggest ways such effects can be minimised or eliminated.