Related papers: Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registers

Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registers

URL: http://arxiv.org/abs/2401.06705v1
Date: Fri, 12 Jan 2024 17:13:55 GMT
Title: Fidelity of photon-mediated entanglement between remote nuclear-spin multi-qubit registers
Authors: W.-R. Hannes, Regina Finsterhoelzl, Guido Burkard
Abstract summary: We investigate how a photonic architecture can be extended from the intrinsic nitrogen spin to multiple $13$C spins per node. Even though the currently achieved degree of control might not be sufficient for large-scale devices, the two schemes are compatible in principle.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The electron spin of a nitrogen-vacancy center in diamond lends itself to the control of proximal $^{13}$C 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 $^{13}$C 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 $^{13}$C 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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