G. Peniakov scite author profile

Quantum dots are arguably the best interface between matter spin qubits and flying photonic qubits. Using quantum dot devices to produce joint spin-photonic states requires the electronic spin qubits to be stored for extended times. Therefore, the study of the coherence of spins of various quantum dot confined charge carriers is important both scientifically and technologically. In this study we report on spin relaxation measurements performed on five different forms of electronic spin qubits confined in the very same quantum dot. In particular, we use all optical techniques to measure the spin relaxation of the confined heavy hole and that of the dark exciton -a long lived electron-heavy hole pair with parallel spins. Our measured results for the spin relaxation of the electron, the heavy-hole, the dark exciton, the negative and the positive trions, in the absence of externally applied magnetic field, are in agreement with a central spin theory which attributes the dephasing of the carriers' spin to their hyperfine interactions with the nuclear spins of the atoms forming the quantum dots. We demonstrate that the heavy hole dephases much slower than the electron. We also show, both experimentally and theoretically, that the dark exciton dephases slower than the heavy hole, due to the electron-hole exchange interaction, which partially protects its spin state from dephasing. arXiv:1808.00284v1 [cond-mat.mes-hall] 1 Aug 2018

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Complete state tomography of a quantum dot spin qubit

Cogan

Peniakov

et al. 2020

Phys. Rev. B

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Semiconductor quantum dots are probably the preferred choice for interfacing anchored, matter spin qubits and flying photonic qubits. While full tomography of a flying qubit or light polarization is in general straightforward, matter spin tomography is a challenging and resource-consuming task.Here we present a novel all-optical method for conducting full tomography of quantum-dot-confined spins. Our method is applicable for electronic spin configurations such as the conduction-band electron, the valence-band hole, and for electron-hole pairs such as the bright and the dark exciton. We excite the spin qubit using short resonantly tuned, polarized optical pulse, which coherently converts the qubit to an excited qubit that decays by emitting a polarized single-photon. We perform the tomography by using two different orthogonal, linearly polarized excitations, followed by time-resolved measurements of the degree of circular polarization of the emitted light from the decaying excited qubit. We demonstrate our method on the dark exciton spin state with fidelity of 0.94, mainly limited by the accuracy of our polarization analyzers. arXiv:1910.05024v1 [quant-ph]

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Towards supersensitive optical phase measurement using a deterministic source of entangled multiphoton states

Peniakov

Beck

et al. 2020

Phys. Rev. B

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Erratum: Depolarization of Electronic Spin Qubits Confined in Semiconductor Quantum Dots [Phys. Rev. X 8 , 041050 (2018)]

Cogan¹,

Kenneth²,

Lindner³

et al. 2021

Phys. Rev. X

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Supersensitive Optical Phase Measurement Using Deterministically Generated Multiphoton Entangled State

Peniakov¹,

Su²,

Beck³

et al. 2019

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G. Peniakov

Depolarization of Electronic Spin Qubits Confined in Semiconductor Quantum Dots

Complete state tomography of a quantum dot spin qubit

Towards supersensitive optical phase measurement using a deterministic source of entangled multiphoton states

Erratum: Depolarization of Electronic Spin Qubits Confined in Semiconductor Quantum Dots [Phys. Rev. X 8 , 041050 (2018)]

Supersensitive Optical Phase Measurement Using Deterministically Generated Multiphoton Entangled State

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