Subdiffraction optical manipulation of the charge state of nitrogen vacancy center in diamond

Chen, Xiangdong; Zou, Chang‐Ling; Gong, Zhao-Jun; Dong, Chun‐Hua; Guo, Guang‐Can; Sun, Fang-Wen

doi:10.1038/lsa.2015.3

Cited by 101 publications

(68 citation statements)

References 43 publications

(67 reference statements)

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“…In addition, MEANS-STED is broadly applicable to PSF engineering-based super-resolution techniques, including the pulsed or time-gated STED 20 , RESOLFT 4 , ground-state depletion, excitation-state absorption, saturation 38 , optical data storage 39 , upconversion 40 and charge-state depletion 41 . Compared with the other imaging techniques based on the recollection of the signal through interference to confine the axial resolution, including 4Pi 15 , I 5 M 14 and wide-field standing-wave microscopy 7 or mirrors combined with spatial light modulator 10,42 , MEANS is much simpler and does not require precise alignment of the mirror.…”

Section: Resultsmentioning

confidence: 99%

Mirror-enhanced super-resolution microscopy

et al. 2016

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Axial excitation confinement beyond the diffraction limit is crucial to the development of next-generation, super-resolution microscopy. STimulated Emission Depletion (STED) nanoscopy offers lateral super-resolution using a donut-beam depletion, but its axial resolution is still over 500 nm. Total internal reflection fluorescence microscopy is widely used for single-molecule localization, but its ability to detect molecules is limited to within the evanescent field of ~ 100 nm from the cell attachment surface. We find here that the axial thickness of the point spread function (PSF) during confocal excitation can be easily improved to 110 nm by replacing the microscopy slide with a mirror. The interference of the local electromagnetic field confined the confocal PSF to a 110-nm spot axially, which enables axial super-resolution with all laser-scanning microscopes. Axial sectioning can be obtained with wavelength modulation or by controlling the spacer between the mirror and the specimen. With no additional complexity, the mirror-assisted excitation confinement enhanced the axial resolution six-fold and the lateral resolution two-fold for STED, which together achieved 19-nm resolution to resolve the inner rim of a nuclear pore complex and to discriminate the contents of 120 nm viral filaments. The ability to increase the lateral resolution and decrease the thickness of an axial section using mirror-enhanced STED without increasing the laser power is of great importance for imaging biological specimens, which cannot tolerate high laser power.

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Section: Resultsmentioning

confidence: 99%

Mirror-enhanced super-resolution microscopy

et al. 2016

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“…2 we show the dynamics of E while increasing the number of spins in the channel with a fixed NV separation of 40 nm [48,49]. We limit ourselves to a maximum of N = 12, since this is approaching the limit of our numerical capability.…”

Section: Resultsmentioning

confidence: 99%

Designing spin-channel geometries for entanglement distribution

2016

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We investigate different geometries of spin-1/2 nitrogen impurity channels for distributing entanglement between pairs of remote nitrogen vacancy centers (NVs) in diamond. To go beyond the system size limits imposed by directly solving the master equation, we implement a matrix product operator method to describe the open system dynamics. In so doing, we provide an early demonstration of how the time-evolving block decimation algorithm can be used for answering a problem related to a real physical system that could not be accessed by other methods. For a fixed NV separation there is an interplay between incoherent impurity spin decay and coherent entanglement transfer: Long-transfer-time, few-spin systems experience strong dephasing that can be overcome by increasing the number of spins in the channel. We examine how missing spins and disorder in the coupling strengths affect the dynamics, finding that in some regimes a spin ladder is a more effective conduit for information than a single-spin chain.

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“…The initialization-depletiondetection procedure repeated hundreds of times to obtain sufficient photons for each scanning pixel. The resolution of CSD nanoscopy is determined by the depletion rate, which can be improved, in principle, by increasing the power of the doughnut-shaped beam 25,26 .…”

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confidence: 99%

“…However, the spatial resolution with conventional optical microscopy is limited by the diffraction. Recently, several different types of optical nanoscopy methods for NV center imaging have been developed [21][22][23][24][25][26][27] . Therefore, it is possible to use NV center ensemble arrays as probes to realize sub-diffraction spatial resolution quantum sensing.…”

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Optical far-field super-resolution microscopy using nitrogen vacancy center ensemble in bulk diamond

Shen

Chen

Yang

et al. 2016

Applied Physics Letters

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We demonstrate an optical far-field super-resolution microscopy using array of nitrogen vacancy centers in bulk diamond as near-field optical probes. The local optical field, which transmits through the nanostructures on the diamond surface, is measured by detecting the charge state conversion of nitrogen vacancy center. And the locating of nitrogen vacancy center with spatial resolution of 6.1 nm is realized with the charge state depletion nanoscopy. The nanostructures on the surface of diamond are then imaged with resolution below optical diffraction limit. The results offer an approach to built a general-purpose optical super-resolution microscopy and a convenient platform for high spatial resolution quantum sensing with nitrogen vacancy center.With stable fluorescence, optically initialized spin state and long spin coherence time, the nitrogen vacancy (NV) center in diamond is a promising candidate for quantum metrology 1,2 . High sensitive detection of electromagnetic field and temperature have been demonstrated with NV center 3-7 , even in living biological cells [8][9][10] . Due to the sub-nanometer size, high spatial resolution is one of the most important advantage of NV based sensors. Typically, it is realized by scanning a specially prepared tip with attached nanodiamond 4,5,11-13 . However, the presence and movement of tips may change the local field distribution at the nanoscale 14,15 . Additionally, the preparation of the tips is usually difficult16 . An alternative method is to replace the scanning tips with highdensity non-scanning array of NV centers, whose relative positions and statuses are obtained through optical far-field microscopy 17-20 . However, the spatial resolution with conventional optical microscopy is limited by the diffraction. Recently, several different types of optical nanoscopy methods for NV center imaging have been developed [21][22][23][24][25][26][27] . Therefore, it is possible to use NV center ensemble arrays as probes to realize sub-diffraction spatial resolution quantum sensing.In particular, the local optical field detection with high spatial resolution is interesting in diverse fields ranging from nanophotonics to biosensing 4,14,15 . In this work, we demonstrate the local optical field detection with subdiffraction resolution using NV center ensemble in bulk diamond as probes, as shown in Fig. 1(a). The light transmitted through nanostructure on the diamond surface is measured with the charge state conversion of nearfield NV center probes. And the high spatial resolution imaging of NV is realized with charge state depletion (CSD) nanoscopy. Subsequently, the sub-diffraction images of the nanostructures on the diamond plate surface are obtained via local optical field detection. A generalpurpose super-resolution Microscopy with Array of Nearfield Probes (MANP) is constructed based on the results. Furthermore, because the NV center is also sensitive to electromagnetic fields, temperature and pressure 28 , the present technique provides a convenient method to establis...

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Subdiffraction optical manipulation of the charge state of nitrogen vacancy center in diamond

Cited by 101 publications

References 43 publications

Mirror-enhanced super-resolution microscopy

Mirror-enhanced super-resolution microscopy

Designing spin-channel geometries for entanglement distribution

Optical far-field super-resolution microscopy using nitrogen vacancy center ensemble in bulk diamond

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