Ideal refocusing of an optically active spin qubit under strong hyperfine interactions.
Leon ZaporskiNoah ShoferJonathan H BodeySantanu MannaGeorge GillardMartin Hayhurst AppelChristian SchimpfSaimon Filipe Covre da SilvaJohn JarmanGeoffroy DelamareGunhee ParkUrs HaeuslerEvgeny A ChekhovichArmando RastelliDorian A GangloffMete AtatüreClaire Le GallPublished in: Nature nanotechnology (2023)
Combining highly coherent spin control with efficient light-matter coupling offers great opportunities for quantum communication and computing. Optically active semiconductor quantum dots have unparalleled photonic properties but also modest spin coherence limited by their resident nuclei. The nuclear inhomogeneity has thus far bound all dynamical decoupling measurements to a few microseconds. Here, we eliminate this inhomogeneity using lattice-matched GaAs-AlGaAs quantum dot devices and demonstrate dynamical decoupling of the electron spin qubit beyond 0.113(3) ms. Leveraging the 99.30(5)% visibility of our optical π-pulse gates, we use up to N π = 81 decoupling pulses and find a coherence time scaling of [Formula: see text]. This scaling manifests an ideal refocusing of strong interactions between the electron and the nuclear spin ensemble, free of extrinsic noise, which holds the promise of lifetime-limited spin coherence. Our findings demonstrate that the most punishing material science challenge for such quantum dot devices has a remedy and constitute the basis for highly coherent spin-photon interfaces.
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