Quantum measurement and orientation tracking of fluorescent nanodiamonds inside living cells

McGuinness, Liam P.; Yan, Yan; Stacey, Alastair; Simpson, David A.; Hall, Liam T.; Maclaurin, Dougal; Prawer, S.; Mulvaney, Paul; Wrachtrup, Jörg; Caruso, Frank; Scholten, R. E.; Hollenberg, Lloyd C. L.

doi:10.1038/nnano.2011.64

Cited by 594 publications

(585 citation statements)

References 36 publications

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“…At the expense of longer integration, scanning techniques such as stimulated emission depletion would boost Dr xy down to 8 nm 38 reaching even single spin sensitivities. Alternatively to our ensemble sensor, local spin densities could be monitored even inside living cells by employing single NVs embedded in nanodiamonds 39,40 . The high temporal resolution of widefield magnetometry favors sub-cellular visualization also of label-free dynamic processes, for instance the production of free radicals in cell death, the regulation of homoeostasis through ion channels 41 or haemoglobin trafficking by imaging paramagnetic oxygen.…”

Section: Discussionmentioning

confidence: 99%

Magnetic spin imaging under ambient conditions with sub-cellular resolution

Steinert¹,

Ziem²,

et al. 2013

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The detection of small numbers of magnetic spins is a significant challenge in the life, physical and chemical sciences, especially when room temperature operation is required. Here we show that a proximal nitrogen-vacancy spin ensemble serves as a high precision sensing and imaging array. Monitoring its longitudinal relaxation enables sensing of freely diffusing, unperturbed magnetic ions and molecules in a microfluidic device without applying external magnetic fields. Multiplexed charge-coupled device acquisition and an optimized detection scheme permits direct spin noise imaging of magnetically labelled cellular structures under ambient conditions. Within 20 s we achieve spatial resolutions below 500 nm and experimental sensitivities down to 1,000 statistically polarized spins, of which only 32 ions contribute to a net magnetization. The results mark a major step towards versatile subcellular magnetic imaging and real-time spin sensing under physiological conditions providing a minimally invasive tool to monitor ion channels or haemoglobin trafficking inside live cells.

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Section: Discussionmentioning

confidence: 99%

Magnetic spin imaging under ambient conditions with sub-cellular resolution

Steinert¹,

Ziem²,

et al. 2013

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“…This defect has the potential to be used for quantum computation, 1-4 nanoscale metrology [5][6][7][8] and biological imaging. [9][10][11] To further extend the study of the interaction between a multi-NV center and the nanoscale sensing with the NV center, it is necessary to detect and control the NV center spin-state dynamics with high spatial resolution. 7,[12][13][14] Therefore, many optical super-resolution microscopy techniques have been developed to detect single NV centers.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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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. Keywords: charge state; NV center; photon ionization; super-resolution microscopy INTRODUCTION Because of the stable fluorescence and long coherence time of its spin state, the negatively charged nitrogen vacancy (NV 2 ) center in diamond has been studied extensively over the past decade. This defect has the potential to be used for quantum computation, 1-4 nanoscale metrology 5-8 and biological imaging. [9][10][11] To further extend the study of the interaction between a multi-NV center and the nanoscale sensing with the NV center, it is necessary to detect and control the NV center spin-state dynamics with high spatial resolution. 7,12-14 Therefore, many optical super-resolution microscopy techniques have been developed to detect single NV centers. [13][14][15][16][17] Among these methods, stimulated emission depletion (STED) microscopy 12,18-20 is one of the most promising. This method utilizes a doughnut-shaped laser to produce the position-dependent stimulated emission, which changes the fluorescence signal. With STED, the electron spin resonance signals of NV centers have been detected with a resolution lower than the diffraction limit. 12,21,22 A new super-resolution microscopy technique was recently developed by Han et al. 15 The authors replaced the stimulated excitation of STED with the dark-state pumping of NV centers. The dark state was later proven to be the neutral charge NV center (NV 0 ) by other groups. [23][24][25] The charge-state conversion results in a change of the local field in diamond 26 and the spectral diffusion of the NV center. 24,27 For high-fidelity quantum manipulation, the charge state should be well controlled. 28 Based on the mechanism of charge-state conversion and super-resolution microscopy, 25,29,30 we demonstrated the optical manipulation of the charge state of an NV center with subdiffraction resolution. By changing the duration and power of laser

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“…[14][15][16][17][18] Furthermore, the center may be incorporated into nano-diamonds, whose chemical inertness and biocompatibility, allow sensing techniques to be performed within living cells. 19 Recently, the center's bio-sensing applications were expanded with the demonstration of sub-cellular temperature gradient mapping and control using NV − nano-diamond and gold nano-particles within a human embryonic fibroblast. 17 This exciting demonstration can be potentially extended to in vivo thermometry and thermoablative therapy.…”

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All-Optical Thermometry and Thermal Properties of the Optically Detected Spin Resonances of the NV^– Center in Nanodiamond

et al. 2014

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Quantum measurement and orientation tracking of fluorescent nanodiamonds inside living cells

Cited by 594 publications

References 36 publications

Magnetic spin imaging under ambient conditions with sub-cellular resolution

Magnetic spin imaging under ambient conditions with sub-cellular resolution

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

All-Optical Thermometry and Thermal Properties of the Optically Detected Spin Resonances of the NV^– Center in Nanodiamond

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Quantum measurement and orientation tracking of fluorescent nanodiamonds inside living cells

Cited by 594 publications

References 36 publications

Magnetic spin imaging under ambient conditions with sub-cellular resolution

Magnetic spin imaging under ambient conditions with sub-cellular resolution

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

All-Optical Thermometry and Thermal Properties of the Optically Detected Spin Resonances of the NV– Center in Nanodiamond

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All-Optical Thermometry and Thermal Properties of the Optically Detected Spin Resonances of the NV^– Center in Nanodiamond