Realisation of electron-spin-pair qubit in diamond
ORAL
Abstract
Realizing quantum networks requires quantum registers next to optically addressable qubits. A variety of
approaches have been reported including recent work on nuclear-spin pairs and single electron spins
surrounding nitrogen-vacancy centers [1, 2]. Here, we investigate a qubit encoded in a pair of electron spins
formed by two P1 centers. We find long inhomogeneous dephasing times of tens of milliseconds, due to a
combination of a decoherence-free subspace and a clock transition. By observing the spin pairs’ temporal
evolution and utilizing RF pulse sequences to address various transitions, we characterize the internal
interactions and resolve the characteristic degrees of freedom of the P1 centers; the Jahn-Teller distortion and
nitrogen state. Using these extra degrees of freedom, we find the P1 centers’ relative position. This work
provides a novel qubit with potential applications in quantum networks and sensing, whilst enriching the
understanding of electronic spin-pair dynamics.
1. Bartling, H. P. et al. Coherence and entanglement of inherently long-lived spin pairs in diamond. arXiv:2103.07961 [quant-ph] (2021).
2. Degen, M. J. et al. Entanglement of dark electron-nuclear spin defects in diamond. Nature Communications 12, 3470 (2021).
approaches have been reported including recent work on nuclear-spin pairs and single electron spins
surrounding nitrogen-vacancy centers [1, 2]. Here, we investigate a qubit encoded in a pair of electron spins
formed by two P1 centers. We find long inhomogeneous dephasing times of tens of milliseconds, due to a
combination of a decoherence-free subspace and a clock transition. By observing the spin pairs’ temporal
evolution and utilizing RF pulse sequences to address various transitions, we characterize the internal
interactions and resolve the characteristic degrees of freedom of the P1 centers; the Jahn-Teller distortion and
nitrogen state. Using these extra degrees of freedom, we find the P1 centers’ relative position. This work
provides a novel qubit with potential applications in quantum networks and sensing, whilst enriching the
understanding of electronic spin-pair dynamics.
1. Bartling, H. P. et al. Coherence and entanglement of inherently long-lived spin pairs in diamond. arXiv:2103.07961 [quant-ph] (2021).
2. Degen, M. J. et al. Entanglement of dark electron-nuclear spin defects in diamond. Nature Communications 12, 3470 (2021).
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Presenters
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Nicolas Demetriou
Delft University of Technology
Authors
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Nicolas Demetriou
Delft University of Technology