Demonstration of Entanglement of Electrostatically Coupled Singlet-Triplet Qubits

Shulman, Michael; Dial, Oliver; Harvey, Shannon; Bluhm, Hendrik; Umansky, V.; Yacoby, Amir

doi:10.1126/science.1217692

Cited by 530 publications

(688 citation statements)

References 31 publications

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“…Such an interface is a central element in quantum sensors and quantum repeaters [6,7], but could also be used to simplify the layout of multi-qubit gated devices [8]. An intermediate step in the transfer of the photon polarization state onto the state of the spin involves generation of an electron-hole pair.…”

mentioning

confidence: 99%

Consequences of Spin-Orbit Coupling at the Single Hole Level: Spin-Flip Tunneling and the Anisotropic g Factor

et al. 2017

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confidence: 99%

Consequences of Spin-Orbit Coupling at the Single Hole Level: Spin-Flip Tunneling and the Anisotropic g Factor

et al. 2017

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“…[49][50][51] Such electrical control has recently been demonstrated for hole spins in III-V nanowire quantum dots, 52 and coherence times have now been measured for hole spins in Ge-Si core-shell nanowire quantum dots. 53 The very recent achievement of the few-hole regime in lateral gated double-dot devices, 54 suggests that previous highly successful measurements performed for electron spins [55][56][57][58][59][60] can now be performed for hole spins, which show promise for much longer coherence times. 33,35 In the rest of this paper, we introduce a general method that can be used to calculate and enhance the purity of a qubit interacting with an anisotropic environment.…”

Section: Introductionmentioning

confidence: 99%

Maximizing the purity of a qubit evolving in an anisotropic environment

2015

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We provide a general method to calculate and maximize the purity of a qubit interacting with an anisotropic non-Markovian environment. Counter to intuition, we find that the purity is often maximized by preparing and storing the qubit in a superposition of non-interacting eigenstates. For a model relevant to decoherence of a heavy-hole spin qubit in a quantum dot or for a singlettriplet qubit for two electrons in a double quantum dot, we show that preparation of the qubit in its non-interacting ground state can actually be the worst choice to maximize purity. We further give analytical results for spin-echo envelope modulations of arbitrary spin components of a hole spin in a quantum dot, going beyond a standard secular approximation. We account for general dynamics in the presence of a pure-dephasing process and identify a crossover timescale at which it is again advantageous to initialize the qubit in the non-interacting ground state. Finally, we consider a general two-axis dynamical decoupling sequence and determine initial conditions that maximize purity, minimizing leakage to the environment.

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“…The singlet (S) and S z = 0 triplet (T 0 ) states of two electrons in a double quantum dot has proven to be a promising candidate for quantum information processing [2,7,20]. The wave functions of the electrons are typi- * Electronic address: halperin@physics.harvard.edu cally spread over ∼ 100 nm and the hyperfine interaction between the electrons and their nuclear environment may include several million nuclei.…”

Section: Introductionmentioning

confidence: 99%

Electron spin-flip correlations due to nuclear dynamics in driven GaAs double dots

et al. 2017

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We present experimental data and associated theory for correlations in a series of experiments involving repeated Landau-Zener sweeps through the crossing point of a singlet state and a spin aligned triplet state in a GaAs double quantum dot containing two conduction electrons, which are loaded in the singlet state before each sweep, and the final spin is recorded after each sweep. The experiments reported here measure correlations on time scales from 4 µs to 2 ms. When the magnetic field is aligned in a direction such that spin-orbit coupling cannot cause spin flips, the correlation spectrum has prominent peaks centered at zero frequency and at the differences of the Larmor frequencies of the nuclei, on top of a frequency-independent background. When the spin-orbit field is relevant, there are additional peaks, centered at the frequencies of the individual species. A theoretical model which neglects the effects of high-frequency charge noise correctly predicts the positions of the observed peaks, and gives a reasonably accurate prediction of the size of the frequency-independent background, but gives peak areas that are larger than the observed areas by a factor of two or more. The observed peak widths are roughly consistent with predictions based on nuclear dephasing times of the order of 60 µs. However, there is extra weight at the lowest observed frequencies, which suggests the existence of residual correlations on the scale of 2 ms. We speculate on the source of these discrepancies.

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Demonstration of Entanglement of Electrostatically Coupled Singlet-Triplet Qubits

Cited by 530 publications

References 31 publications

Consequences of Spin-Orbit Coupling at the Single Hole Level: Spin-Flip Tunneling and the Anisotropic g Factor

Consequences of Spin-Orbit Coupling at the Single Hole Level: Spin-Flip Tunneling and the Anisotropic g Factor

Maximizing the purity of a qubit evolving in an anisotropic environment

Electron spin-flip correlations due to nuclear dynamics in driven GaAs double dots

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