Subdiffraction optical manipulation of the charge state of nitrogen vacancy center in diamond
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Abstract
As a potential candidate for quantum computation and metrology, the nitrogen vacancy (NV) center in diamond presents both challenges and opportunities resulting from charge-state conversion. By utilizing different lasers for the photon-induced charge-state conversion, we achieved subdiffraction charge-state manipulation. The charge-state depletion (CSD) microscopy resolution was improved to 4.1 nm by optimizing the laser pulse sequences. Subsequently, the electron spin-state dynamics of adjacent NV centers were selectively detected via the CSD. The experimental results demonstrated that the CSD can improve the spatial resolution of the measurement of NV centers for nanoscale sensing and quantum information. The nitrogen vacancy (NV) in diamond is useful for quantum optics and spintronics due to the long coherence time of its electron spin state. Scientists in China have now used the techniques of super-resolution microscopy to optically control the charge state of an NV defect with a subdiffraction spatial resolution of 4.1 nm. Xiangdong Chen and co-workers from the University of Science and Technology of China in Hefei used a green (532 nm) laser beam to switch the charge state of the defect between NV0 and NV–. They achieved this manipulation on a subdiffraction scale by using specially shaped doughnut laser beams, in common with the principles of super-resolution stimulated emission depletion microscopy. This achievement represents a significant step towards nanoscale sensing and quantum information processing.
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