Spectrum of the Nuclear Environment for GaAs Spin Qubits

Malinowski, Filip K.; Martins, Frederico Rodrigues; Cywiński, Łukasz; Rudner, Mark S.; Nissen, Peter D.; Fallahi, Saeed; Gardner, Geoffrey C.; Manfra, Michael J.; Marcus, C. M.; Kuemmeth, Ferdinand

doi:10.1103/physrevlett.118.177702

Cited by 83 publications

(93 citation statements)

References 46 publications

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“…The power spectral density of δf in Ramsey measurements is calculated by the fast Fourier transform of δf (t). The spectral density taken with small SEC and feedback off (blue) shows the f −1.7 dependence (black dashed line) similar to those observed for nuclear spin diffusion noise [15,16]. The spectral density is significantly suppressed with feedback on (orange) down to a level determined by the precision of the feedback control.…”

Section: Improvements Of the Qubit Controlsupporting

confidence: 57%

“…Approximating S(f ) = A 2 /f , however, we find A ∼ 0.6 MHz being two orders of magnitude larger than A ∼ 1.6 kHz found in the 28 Si device. It is also an order of magnitude larger than A ∼ 0.1 MHz observed in a GaAs device without micromagnet [16]. The difference can be partly attributed to large SEC in the present device, as S(f ) is reduced by two orders of magnitude by decreasing SEC (see Fig.…”

Section: Improvements Of the Qubit Controlcontrasting

confidence: 48%

“…It suggests that the f −1 noise background in the range of tens of MHz is the dominant limiting factor of the qubit control fidelity. The f −β dependence with β = 1 differs from β ∼ 1.7 for the nuclear spin diffusion noise [15,16] at low frequencies (see Fig. 5b) extracted from the data in Figs.…”

Section: Improvements Of the Qubit Controlmentioning

confidence: 91%

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Coherence of a Driven Electron Spin Qubit Actively Decoupled from Quasistatic Noise

et al. 2020

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The coherence of electron spin qubits in semiconductor quantum dots suffers mostly from lowfrequency noise. During the last decade, efforts have been devoted to mitigate such noise by material engineering, leading to substantial enhancement of the spin dephasing time for an idling qubit. However, the role of the environmental noise during spin manipulation, which determines the control fidelity, is less understood. We demonstrate an electron spin qubit whose coherence in the driven evolution is limited by high-frequency charge noise rather than the quasi-static noise inherent to any semiconductor device. We employed a feedback control technique to actively suppress the latter, demonstrating a π-flip gate fidelity as high as 99.04 ± 0.23 % in a gallium arsenide quantum dot. We show that the driven-evolution coherence is limited by the longitudinal noise at the Rabi frequency, whose spectrum resembles the 1/f noise observed in isotopically purified silicon qubits.

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Section: Improvements Of the Qubit Controlsupporting

confidence: 57%

Section: Improvements Of the Qubit Controlcontrasting

confidence: 48%

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Coherence of a Driven Electron Spin Qubit Actively Decoupled from Quasistatic Noise

et al. 2020

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“…2. Here we have treated the disorder as quasistatic, but in a QD system it is mostly due to the fluctuations of the nuclear spins, and so it varies slowly over timescales longer than a few microseconds [30,43]. Thus, the true limits on the spin preservation time are likely shorter than the ones obtained within the present model.…”

Section: Discrete Time Crystalmentioning

confidence: 77%

Discrete time crystal in the gradient-field Heisenberg model

Dyke

Warren

et al. 2020

Phys. Rev. B

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We show that time crystal phases, which are known to exist for disorder-based many-body localized systems, also appear in systems where localization is due to strong magnetic field gradients. Specifically, we study a finite Heisenberg spin chain in the presence of a gradient field, which can be realized experimentally in quantum dot systems using micromagnets or nuclear spin polarization. Our numerical simulations reveal time crystalline order over a broad range of realistic quantum dot parameters, as evidenced by the long-time preservation of spin expectation values and the asymptotic form of the mutual information. We also consider the undriven system and present several diagnostics for many-body localization that are complementary to those recently studied. Our results show that these non-ergodic phases should be realizable in modest-sized quantum dot spin arrays using only demonstrated experimental capabilities. arXiv:1912.05130v1 [quant-ph]

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“…The application of such a sequence leads then to dynamical decoupling [5,[14][15][16][17]] that on one hand extends qubits's coherence time by suppressing the influence of most of environmental fluctuations, and on the other makes the qubit sensitive to noise frequencies determined by the inverse of applied sequence period [5][6][7][8][9]. This method has been successfully implemented with many kinds of qubits: superconducting circuits [7], trapped ions [9], ultracold atoms [18], semiconductor-based quantum dots [19][20][21], donors in silicon [22], and nitrogen-vacancy centers in diamond [23,24]. The information obtained in this way led to multiple new insights into the dynamics of environments affecting various kind of qubits.…”

Section: Introductionmentioning

confidence: 99%

The dynamical-decoupling-based spatiotemporal noise spectroscopy

2019

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Here we demonstrate how the standard, temporal-only, dynamical-decoupling-based noise spectroscopy method can be extended to also encompass the spatial degree of freedom. This spatiotemporal spectroscopy utilizes a system of multiple qubits arranged in a line that are undergoing pure dephasing due to environmental noise. When the qubits are driven by appropriately coordinated sequences of π pulses the multi-qubit register becomes decoupled from all components of the noise, except for those characterized by frequencies and wavelengths specified by the pulse sequences. This allows for employment of the procedure for reconstruction of the two-dimensional spectral density that quantifies the power distribution among spatial and temporal harmonic components of the noise.

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Spectrum of the Nuclear Environment for GaAs Spin Qubits

Cited by 83 publications

References 46 publications

Coherence of a Driven Electron Spin Qubit Actively Decoupled from Quasistatic Noise

Coherence of a Driven Electron Spin Qubit Actively Decoupled from Quasistatic Noise

Discrete time crystal in the gradient-field Heisenberg model

The dynamical-decoupling-based spatiotemporal noise spectroscopy

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