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Characterization of hyperfine interaction between single electron and single nuclear spins in diamond assisted by quantum beat from the nuclear spin

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abstract

Precise characterization of a hyperfine interaction is a prerequisite for high fidelity manipulations of electron and nuclear spins belonging to a hybrid qubit register in diamond. Here, we demonstrate a novel scheme for determining a hyperfine interaction, using single-quantum and zero-quantum Ramsey fringes, by applying it to the system of a Nitrogen Vacancy (NV) center and a $^{13}$C nuclear spin in the 1$^{\mathrm{st}}$ shell. The zero-quantum Ramsey fringe, analogous to the quantum beat in a $\Lambda$-type level structure, particularly enhances the measurement precision for non-secular hyperfine terms. Precisions less than 0.5 MHz in the estimation of all the components in the hyperfine tensor were achieved. Furthermore, for the first time we experimentally determined the principal axes of the hyperfine interaction in the system. Beyond the 1$^{\mathrm{st}}$ shell, this method can be universally applied to other $^{13}$C nuclear spins interacting with the NV center.

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quant-ph 1

years

2019 1

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UNVERDICTED 1

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Repetitive Readout Enhanced by Machine Learning

quant-ph · 2019-07-27 · unverdicted · novelty 6.0

Machine learning on time traces of repetitive qubit readouts improves fidelity over threshold photon counting by identifying back-action.

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  • Repetitive Readout Enhanced by Machine Learning quant-ph · 2019-07-27 · unverdicted · none · ref 36 · internal anchor

    Machine learning on time traces of repetitive qubit readouts improves fidelity over threshold photon counting by identifying back-action.