Reduced Sensitivity to Charge Noise in Semiconductor Spin Qubits via Symmetric Operation

Reed, Matthew; Maune, Brett; Andrews, Reed W.; Borselli, Matthew; Eng, Kevin; Jura, M.; Kiselev, A. A.; Ladd, Thaddeus D.; Merkel, Seth; Milosavljevic, I.; Pritchett, Emily; Rakher, Matthew T.; Ross, Richard S.; Schmitz, A.; Smith, Aaron; Wright, Jeffrey A.; Gyure, Mark F.; Hunter, A. T.

doi:10.1103/physrevlett.116.110402

Cited by 257 publications

(271 citation statements)

References 34 publications

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“…Coherent evolution of excitations in charge and spin can span many sites, as, contrary to what might be expected, dissipation and decoherence rates induced by electromagnetic noise can be made > 20 times smaller than the relevant coupling energies [20,22,23]. Furthermore, local control and read-out of both charge and spin degrees of freedom have become matured areas of research, given the large ongoing effort of using quantum dots as a platform for quantum information processing [17,18,19,20,21,22,23]. In particular, excellent control of small on-site energy differences [20,28] or tunnel couplings [22,23] has been shown at specific values of electron filling and tuning.…”

Section: Introductionmentioning

confidence: 87%

“…As such, pure state initialization of highly-entangled states is possible even without the use of adiabatic initialization schemes [27]. Coherent evolution of excitations in charge and spin can span many sites, as, contrary to what might be expected, dissipation and decoherence rates induced by electromagnetic noise can be made > 20 times smaller than the relevant coupling energies [20,22,23]. Furthermore, local control and read-out of both charge and spin degrees of freedom have become matured areas of research, given the large ongoing effort of using quantum dots as a platform for quantum information processing [17,18,19,20,21,22,23].…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, local control and read-out of both charge and spin degrees of freedom have become matured areas of research, given the large ongoing effort of using quantum dots as a platform for quantum information processing [17,18,19,20,21,22,23]. In particular, excellent control of small on-site energy differences [20,28] or tunnel couplings [22,23] has been shown at specific values of electron filling and tuning. Quantum simulation experiments can leverage many of these developments, trading off some of the experimental difficulties involved in full coherent control for ease of scaling.…”

Section: Introductionmentioning

confidence: 99%

“…Seminal efforts are underway in the control of artificial quantum systems, that can be made to emulate the underlying Fermi-Hubbard models [5, 6, 7, 8,9,10,11]. Electrostatically confined conduction band electrons define interacting quantum coherent spin and charge degrees of freedom that allow all-electrical pure-state initialisation and readily adhere to an engineerable Fermi-Hubbard Hamiltonian [12,13,14,15,16,17,18,19,20,21,22,23]. Until now, however, the substantial electrostatic disorder inherent to solid state has made attempts at emulating Fermi-Hubbard physics on solid-state platforms few and far between [24,25].…”

mentioning

confidence: 99%

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Quantum simulation of a Fermi–Hubbard model using a semiconductor quantum dot array

Hensgens

Fujita

Janssen

et al. 2017

Nature

310

329

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Interacting fermions on a lattice can develop strong quantum correlations, which lie at the heart of the classical intractability of many exotic phases of matter [1, 2, 3, 4]. Seminal efforts are underway in the control of artificial quantum systems, that can be made to emulate the underlying Fermi-Hubbard models [5, 6, 7, 8,9,10,11]. Electrostatically confined conduction band electrons define interacting quantum coherent spin and charge degrees of freedom that allow all-electrical pure-state initialisation and readily adhere to an engineerable Fermi-Hubbard Hamiltonian [12,13,14,15,16,17,18,19,20,21,22,23]. Until now, however, the substantial electrostatic disorder inherent to solid state has made attempts at emulating Fermi-Hubbard physics on solid-state platforms few and far between [24,25]. Here, we show that for gate-defined quantum dots, this disorder can be suppressed in a controlled manner. Novel insights and a newly developed semi-automated and scalable toolbox allow us to homogeneously and independently dial in the electron filling and nearest-neighbour tunnel coupling. Bringing these ideas and tools to fruition, we realize the first detailed characterization of the collective Coulomb blockade transition [26], which is the finite-size analogue of the interaction-driven Mott metal-to-insulator transition [1]. As automation and device fabrication of semiconductor quantum dots continue to improve, the ideas presented here show how quantum dots can be used to investigate the physics of ever more complex many-body states.

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Section: Introductionmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Quantum simulation of a Fermi–Hubbard model using a semiconductor quantum dot array

Hensgens

Fujita

Janssen

et al. 2017

Nature

310

329

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“…This is possible since the sweet spot is independent of the tunneling elements. The idea of tuning the tunneling barrier directly to control the exchange interaction (as opposed to changing the relative energy-level detuning between two dots), which was the original idea of QD spin qubits [1], has been successfully demonstrated in recent experiments in Si/SiGe [24] and GaAs/AlGaAs [26] QD devices. The exchange operation via gate-tuning the tunneling barrier near the symmetric operating point (SOP) of the detuning leads to much higher fidelity during the exchange operations than the conventional control of the exchange interaction by tilting (detuning) the double dot system.…”

mentioning

confidence: 99%

Charge-noise-insensitive gate operations for always-on, exchange-only qubits

2016

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We introduce an always-on, exchange-only qubit made up of three localized semiconductor spins that offers a true "sweet spot" to fluctuations of the quantum dot energy levels. Both single-and two-qubit gate operations can be performed using only exchange pulses while maintaining this sweet spot. We show how to interconvert this qubit to other three-spin encoded qubits as a new resource for quantum computation and communication.Semiconductor qubits [1,2] are a leading candidate technology for quantum information processing [3]. Spins can have extremely long quantum coherence due to a decoupling of spin information from charge noise in many materials, and they are small, enabling high density. But these strengths pose a challenge for control as microwave pulses generally result in slow gates with significant potential for crosstalk to nearby qubits. The exchange interaction on the other hand provides a natural and fast method for entangling semiconductor qubits: it can be used to perform two-spin entangling operations with a finite-length voltage pulse or to couple spins with a constant interaction. Exchange also provides a solution to the control problem by allowing a two-level system to be encoded into the greater Hilbert space of multiple physical spins. Following work on decoherence free subspaces and subsystems (DFS) [4][5][6], many multi-spinbased qubits have been proposed and demonstrated with various desirable properties for quantum computing: as examples, 2-DFS (a.k.a. "singlet-triplet") [7][8][9][10], 3-DFS (a.k.a. "exchange-only") [11][12][13][14], or 4-DFS qubits [15] of various implementations are possible. The DFS gives some immunity to global field fluctuations, but more importantly it allows for gate operations via a sequence of pair-wise exchange interactions between spins with fast, baseband voltage control on the metallic top-gates, obviating the need for RF pulses. However, charge noise likely limits gate fidelity [16,17] as charge and spin are coupled while spins undergo exchange.The effects of charge (or other) noise on memory or gate fidelity can be suppressed to a certain extent by taking advantage of natural or engineered "sweet" spots: a spot in parameter space where critical system properties are minimally effected by certain environmental changes. Sweet spots have been an effective tool to increase the coherence of superconducting qubits [18,19] and more recently have been applied to exchange-only qubits [20][21][22][23][24]. For example, in the "resonant exchange" (RX) qubit-an encoded qubit made out of 3 quantum dot qubits with "always-on" exchange interactions and a much higher chemical potential for the middle dot than the outer dots-a partial sweet spot is maintained while microwave control allows for single qubit operations [20,21] "resonant" with the gap of the 3-spin system. The first derivative of the RX qubit frequency vanishes for one of the two detuning parameters that are affected by charge noise. For two qubit gates, the RX qubit offers a relatively large transition dipole...

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Efficient Pulse‐Excitation Techniques for Single Photon Sources from Quantum Dots in Optical Cavities

Gustin

Hughes

2019

Adv Quantum Tech

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Rigorous and intuitive master equation models are presented to study on‐demand single photon sources from pulse‐excited quantum dots coupled to optical cavities. Three methods of source excitation are considered: resonant pi‐pulse, off‐resonant phonon‐assisted inversion, and two‐photon excitation of a biexciton–exciton cascade, and the effect of the pulse excitation process on the quantum indistinguishability, efficiency, and purity of emitted photons is investigated. By explicitly modelling the time‐dependent pulsed excitation process in a manner which captures non‐Markovian effects associated with coupling to photon and phonon reservoirs, it is found that photons of near‐unity indistinguishability can be emitted with over 90% efficiency for all these schemes, with the off‐resonant schemes not necessarily requiring polarization filtering due to the frequency separation of the excitation pulse, and allowing for very high single photon purities. Furthermore, the off‐resonant methods are shown to be robust over certain parameter regimes, with less stringent requirements on the excitation pulse duration in particular. Also, a semi‐analytical simplification of the master equation is derived for the off‐resonant drive, which gives insight into the important role that exciton–phonon decoupling for a strong drive plays in the off‐resonant phonon‐assisted inversion process.

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Reduced Sensitivity to Charge Noise in Semiconductor Spin Qubits via Symmetric Operation

Cited by 257 publications

References 34 publications

Quantum simulation of a Fermi–Hubbard model using a semiconductor quantum dot array

Quantum simulation of a Fermi–Hubbard model using a semiconductor quantum dot array

Charge-noise-insensitive gate operations for always-on, exchange-only qubits

Efficient Pulse‐Excitation Techniques for Single Photon Sources from Quantum Dots in Optical Cavities

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