Related papers: Coherent Control of Quantum-Dot Spins with Cyclic Optical Transitions

Coherent Control of Quantum-Dot Spins with Cyclic Optical Transitions

URL: http://arxiv.org/abs/2509.14445v1
Date: Wed, 17 Sep 2025 21:37:50 GMT
Title: Coherent Control of Quantum-Dot Spins with Cyclic Optical Transitions
Authors: Zhe Xian Koong, Urs Haeusler, Jan M. Kaspari, Christian Schimpf, Benyam Dejen, Ahmed M. Hassanen, Daniel Graham, Ailton J. Garcia Jr., Melina Peter, Edmund Clarke, Maxime Hugues, Armando Rastelli, Doris E. Reiter, Mete Atatüre, Dorian A. Gangloff,
Abstract summary: Solid-state spins are promising as interfaces from stationary qubits to single photons for quantum communication technologies.<n>We show that it is compatible with the operation of a nuclear quantum memory.<n>Our approach enables repeated emission of indistinguishable photons together with qubit control, as required for single-shot readout, photonic cluster-state generation, and quantum repeater technologies.
Score: 0.1213707023442356
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Solid-state spins are promising as interfaces from stationary qubits to single photons for quantum communication technologies. Semiconductor quantum dots have excellent optical coherence, exhibit near unity collection efficiencies when coupled to photonic structures, and possess long-lived spins for quantum memory. However, the incompatibility of performing optical spin control and single-shot readout simultaneously has been a challenge faced by almost all solid-state emitters. To overcome this, we leverage light-hole mixing to realize a highly asymmetric lambda system in a negatively charged heavy hole exciton in Faraday configuration. By compensating GHz-scale differential Stark shifts, induced by unequal coupling to Raman control fields, and by performing nuclear-spin cooling, we achieve quantum control of an electron-spin qubit with a $\pi$-pulse contrast of 97.4% while preserving spin-selective optical transitions with a cyclicity of 409. We demonstrate this scheme for both GaAs and InGaAs quantum dots, and show that it is compatible with the operation of a nuclear quantum memory. Our approach thus enables repeated emission of indistinguishable photons together with qubit control, as required for single-shot readout, photonic cluster-state generation, and quantum repeater technologies.

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