Limits for coherent optical control of quantum emitters in layered materials

TL;DR

This paper investigates the fundamental limits of coherent optical control of quantum emitters in layered materials, focusing on decoherence mechanisms and temperature effects to enable higher-temperature quantum device operation.

Contribution

It provides new insights into decoherence mechanisms affecting quantum emitters in hexagonal boron nitride, especially near the mechanical isolation threshold, advancing understanding of temperature-dependent coherence limits.

Findings

Identified temperature-dependent dephasing mechanisms

Determined the temperature limit for coherent control

Studied the onset of mechanical isolation collapse

Abstract

The coherent control of a two-level system is among the most essential challenges in modern quantum optics. Understanding its fundamental limitations is crucial, also for the realization of next generation quantum devices. The quantum coherence of a two level system is fragile in particular, when the two levels are connected via an optical transition. When such quantum emitters are located in solids the coherence suffers from the interaction of the optical transition with the solid state environment, which requires the sample to be cooled to temperatures of a few Kelvin or below. Here, we use a mechanically isolated quantum emitter in hexagonal boron nitride to explore the individual mechanisms which affect the coherence of an optical transition under resonant drive. We operate the system at the threshold where the mechanical isolation collapses in order to study the onset and temperature-dependence of dephasing and independently of spectral diffusion. The new insights on the underlying physical decoherence mechanisms reveals a limit in temperature until which coherent driving of the system is possible. This study enables to increase the operation temperature of quantum devices, therefore reducing the need for cryogenic cooling.