Publikation: Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registers
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The electron spin of a nitrogen-vacancy center in diamond lends itself to the control of proximal 13C nuclear spins via dynamical decoupling methods, possibly combined with radio-frequency driving. Long-lived single-qubit states and high-fidelity electron-nuclear gates required for the realization of a multiqubit register have already been demonstrated. Towards the goal of a scalable architecture, linking multiple such registers in a photonic network represents an important step. Multiple pairs of remotely entangled qubits can enable advanced algorithms or error correction protocols. We investigate how a photonic architecture can be extended from the intrinsic nitrogen spin to multiple 13C spins per node. Applying decoherence-protected gates sequentially, we simulate the fidelity of creating multiple pairs of remotely entangled qubits. Even though the currently achieved degree of control of 13C spins might not be sufficient for large-scale devices, the two schemes are compatible in principle. One requirement is the correction of unconditional phases acquired by unaddressed nuclear spins during a decoupling sequence.
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HANNES, Wolf-Rüdiger, Regina FINSTERHOELZL, Guido BURKARD, 2024. Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registersBibTex
@unpublished{Hannes2024Fidel-71311, year={2024}, doi={10.48550/arXiv.2401.06705}, title={Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registers}, author={Hannes, Wolf-Rüdiger and Finsterhoelzl, Regina and Burkard, Guido} }
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