Experimental study of PbV centers reports 12 ms spin lifetime at 7.5 K, coherent population trapping, and 177 ns dephasing at 6.5 K, highlighting thermal robustness above 4 K.
Ten-Second Electron-Spin Coherence in Isotopically Engineered Diamond
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abstract
Solid-state spin defects are a promising platform for quantum networks. A key requirement is to combine long ground-state spin-coherence times with a coherent optical transition for spin-photon entanglement. Here, we investigate the spin and optical coherence of single nitrogen-vacancy (NV) centres in (111)-grown isotopically engineered diamond. Our diamond-growth process yields a precisely controlled $^{13}\mathrm{C}$ concentration and low-ppb nitrogen concentrations. Combined with the mitigation of 50 Hz noise using a real-time feedforward scheme and tailored decoupling sequences, this enables record defect-electron-spin coherence times of $T_2 = 6.8(1)$ ms for a Hahn echo and of $T_2^{DD} = 11.2(8)$ s under dynamical decoupling. In addition, we observe coherent optical transitions with a near-lifetime-limited homogeneous linewidth of 16.9(4) MHz and characterize the spectral diffusion dynamics. These results provide new avenues to investigate the incorporation of impurities in diamond and new opportunities for improved spin-qubit control for quantum networks and other quantum technologies.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Coherent Dark State Formation of a Lead-Vacancy Spin Qubit in Diamond
Experimental study of PbV centers reports 12 ms spin lifetime at 7.5 K, coherent population trapping, and 177 ns dephasing at 6.5 K, highlighting thermal robustness above 4 K.