Gate fidelity and coherence of an electron spin in an Si/SiGe quantum dot with micromagnet

The gate fidelity and the coherence time of a quantum bit (qubit) are important benchmarks for quantum computation. We construct a qubit using a single electron spin in an Si/SiGe quantum dot and control it electrically via an artificial spin-orbit field from a micromagnet. We measure an average single-qubit gate fidelity of ∼99% using randomized benchmarking, which is consistent with dephasing from the slowly evolving nuclear spins in the substrate. The coherence time measured using dynamical decoupling extends up to ∼400 μs for 128 decoupling pulses, with no sign of saturation. We find evidence that the coherence time is limited by noise in the 10-kHz to 1-MHz range, possibly because charge noise affects the spin via the micromagnet gradient. This work shows that an electron spin in an Si/SiGe quantum dot is a good candidate for quantum information processing as well as for a quantum memory, even without isotopic purification.

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Exploring Through-Space Spin–Spin Couplings for Quantum Information Processing: Facing the Challenge of Coherence Time and Control Quantum States

The Journal of Physical Chemistry A ◽

10.1021/acs.jpca.8b09425 ◽

2019 ◽

Vol 123 (7) ◽

pp. 1372-1379 ◽

Cited By ~ 3

Author(s):

Jéssica Boreli dos Reis Lino ◽

Teodorico Castro Ramalho

Keyword(s):

Information Processing ◽

Quantum Information ◽

Quantum Information Processing ◽

Coherence Time ◽

Quantum States ◽

And Control

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Towards quantum networks of single spins: analysis of a quantum memory with an optical interface in diamond

Faraday Discussions ◽

10.1039/c5fd00113g ◽

2015 ◽

Vol 184 ◽

pp. 173-182 ◽

Cited By ~ 16

Author(s):

M. S. Blok ◽

N. Kalb ◽

A. Reiserer ◽

T. H. Taminiau ◽

R. Hanson

Keyword(s):

Quantum Information Processing ◽

Quantum States ◽

Nitrogen Vacancy ◽

Nuclear Spins ◽

Quantum Repeater ◽

Quantum Networks ◽

Entanglement Generation ◽

Quantum Bit ◽

Single Defect ◽

Coupling Parameters

Single defect centers in diamond have emerged as a powerful platform for quantum optics experiments and quantum information processing tasks. Connecting spatially separated nodes via optical photons into a quantum network will enable distributed quantum computing and long-range quantum communication. Initial experiments on trapped atoms and ions as well as defects in diamond have demonstrated entanglement between two nodes over several meters. To realize multi-node networks, additional quantum bit systems that store quantum states while new entanglement links are established are highly desirable. Such memories allow for entanglement distillation, purification and quantum repeater protocols that extend the size, speed and distance of the network. However, to be effective, the memory must be robust against the entanglement generation protocol, which typically must be repeated many times. Here we evaluate the prospects of using carbon nuclear spins in diamond as quantum memories that are compatible with quantum networks based on single nitrogen vacancy (NV) defects in diamond. We present a theoretical framework to describe the dephasing of the nuclear spins under repeated generation of NV spin-photon entanglement and show that quantum states can be stored during hundreds of repetitions using typical experimental coupling parameters. This result demonstrates that nuclear spins with weak hyperfine couplings are promising quantum memories for quantum networks.

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Fast spin-valley-based quantum gates in Si with micromagnets

npj Quantum Information ◽

10.1038/s41534-021-00500-4 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Peihao Huang ◽

Xuedong Hu

Keyword(s):

Electron Spin ◽

Quantum Information Processing ◽

Spin Orbit Coupling ◽

Spin Dephasing ◽

Spin Qubit ◽

Electrical Manipulation ◽

Charge Noise ◽

Fast Spin ◽

Sweet Spots

AbstractAn electron spin qubit in silicon quantum dots holds promise for quantum information processing due to the scalability and long coherence. An essential ingredient to recent progress is the employment of micromagnets. They generate a synthetic spin–orbit coupling (SOC), which allows high-fidelity spin manipulation and strong interaction between an electron spin and cavity photons. To scaled-up quantum computing, multiple technical challenges remain to be overcome, including controlling the valley degree of freedom, which is usually considered detrimental to a spin qubit. Here, we show that it is possible to significantly enhance the electrical manipulation of a spin qubit through the effect of constructive interference and the large spin-valley mixing. To characterize the quality of spin control, we also studied spin dephasing due to charge noise through spin-valley mixing. The competition between the increased control strength and spin dephasing produces two sweet-spots, where the quality factor of the spin qubit can be high. Finally, we reveal that the synthetic SOC leads to distinctive spin relaxation in silicon, which explains recent experiments.

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Indications of a soft cutoff frequency in the charge noise of a Si/SiGe quantum dot spin qubit

Physical Review B ◽

10.1103/physrevb.99.081301 ◽

2019 ◽

Vol 99 (8) ◽

Cited By ~ 3

Author(s):

Utkan Güngördü ◽

J. P. Kestner

Keyword(s):

Quantum Dot ◽

Cutoff Frequency ◽

Spin Qubit ◽

Sige Quantum Dot ◽

Charge Noise

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Algorithmic decomposition for efficient multiple nuclear spin detection in diamond

Scientific Reports ◽

10.1038/s41598-020-71339-6 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Hyunseok Oh ◽

Jiwon Yun ◽

M. H. Abobeih ◽

Kyung-Hoon Jung ◽

Kiho Kim ◽

...

Keyword(s):

Hyperfine Interaction ◽

Nuclear Spin ◽

Systematic Approach ◽

Quantum Information Processing ◽

Nitrogen Vacancy ◽

Nuclear Spectroscopy ◽

Nuclear Spins ◽

Systematic Analysis ◽

And Control ◽

Spin Detection

Abstract Efficiently detecting and characterizing individual spins in solid-state hosts is an essential step to expand the fields of quantum sensing and quantum information processing. While selective detection and control of a few 13C nuclear spins in diamond have been demonstrated using the electron spin of nitrogen-vacancy (NV) centers, a reliable, efficient, and automatic characterization method is desired. Here, we develop an automated algorithmic method for decomposing spectral data to identify and characterize multiple nuclear spins in diamond. We demonstrate efficient nuclear spin identification and accurate reproduction of hyperfine interaction components for both virtual and experimental nuclear spectroscopy data. We conduct a systematic analysis of this methodology and discuss the range of hyperfine interaction components of each nuclear spin that the method can efficiently detect. The result demonstrates a systematic approach that automatically detects nuclear spins with the aid of computational methods, facilitating the future scalability of devices.

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