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arxiv: 2406.07267 · v3 · pith:BSQH2GHV · submitted 2024-06-11 · cond-mat.mes-hall · quant-ph

High-fidelity single-spin shuttling in silicon

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classification cond-mat.mes-hall quant-ph
keywords electronquantumshuttlingspinconnectivityqubitscoherencedistance
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The computational power and fault-tolerance of future large-scale quantum processors derive in large part from the connectivity between the qubits. One approach to increase connectivity is to engineer qubit-qubit interactions at a distance. Alternatively, the connectivity can be increased by physically displacing the qubits. This has been explored in trapped-ion experiments and using neutral atoms trapped with optical tweezers. For semiconductor spin qubits, several studies have investigated spin coherent shuttling of individual electrons, but high-fidelity transport over extended distances remains to be demonstrated. Here we report shuttling of an electron inside an isotopically purified Si/SiGe heterostructure using electric gate potentials. First, we form static quantum dots, and study how spin coherence decays as we repeatedly move a single electron between up to five dots. Next, we create a traveling wave potential to transport an electron in a moving quantum dot. This second method shows substantially better spin coherence than the first. It allows us to displace an electron over an effective distance of 10 $\mu$m in under 200 ns with an average fidelity of 99.5%. These results will guide future efforts to realize large-scale semiconductor quantum processors, making use of electron shuttling both within and between qubit arrays.

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Cited by 3 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Using a spin-triplet encoding to enhance shuttling fidelities in Si/SiGe quantum wells

    cond-mat.mes-hall 2026-05 unverdicted novelty 6.0

    A spin-triplet encoding based on valley-singlet states makes shuttling fidelities in Si/SiGe quantum wells higher and more robust to small valley splittings by suppressing Landau-Zener excitations.

  2. CAbLECAR: efficiently scheduling QLDPC codes on a tileable spin qubit chip with shuttling

    quant-ph 2026-04 unverdicted novelty 6.0

    CAbLECAR provides a robotics-inspired shuttle scheduler that enables QLDPC codes on tileable spin-qubit hardware, yielding up to 86% faster schedules and orders-of-magnitude gains in encoding efficiency and logical er...

  3. Decoherence and fidelity enhancement during shuttling of entangled spin qubits

    cond-mat.mes-hall 2025-06 unverdicted novelty 5.0

    Noise correlations in shuttling entangled spin qubits can be exploited via logical encoding in two consecutively shuttled spins to achieve high fidelity even for very slow shuttling.