Hybrid acousto-optical swing-up state control in a quantum dot

TL;DR

This paper introduces a hybrid acousto-optical method for non-resonant charge state control in quantum dots, enabling flexible state preparation and potential for entanglement and on-chip quantum state transfer.

Contribution

It presents a novel hybrid acousto-optical approach for quantum dot charge control that does not require pulse shaping and is robust against decoherence at higher temperatures.

Findings

Effective non-resonant charge state control demonstrated

Method is robust against decoherence at elevated temperatures

Potential for entanglement and on-chip quantum transfer

Abstract

State transfer between different quantum systems is key for successful quantum technologies. Over long distances, photons are irreplaceable, but on short ranges in miniaturized complex devices or hybrid systems, coupling via orders of magnitude shorter-wavelength acoustic waves has great potential. With interfaces to light, acoustic waves, and more, optically active quantum dots (QDs) are essential for multi-component systems. Here, we propose a hybrid acousto-optical method for non-resonant QD charge state control, extending the recent all-optical swing-up state preparation. We show that exciton and biexciton states, or other superpositions of charge states, can be prepared. Each field can act as a trigger, allowing for the implementation of either an optically gated acoustic control or the opposite scheme, where an optical pulse controls the transition during acoustic modulation. Thus, we introduce acoustic state control into a system that lacks direct acoustic coupling between the states. The method does not rely on pulse shaping and is expected to work with arbitrary pulse shapes as long as the optical dressing is performed quasi-adiabatically. Evaluating the phonon impact, we find an almost decoherence-free exciton preparation even at elevated temperatures with current QD and acoustic technology. This approach may also pave the way for optically controlled entanglement between emitters and acoustic modes, and further on-chip state transfer via quantum acoustic buses.