Nitrogen and Luminescent Nitrogen‐Vacancy Defects in Detonation Nanodiamond

Власов, И. И.; Shenderova, Olga; Turner, Stuart; Lebedev, Oleg I.; Basov, A. A.; Силдос, И.; Rähn, Mihkel; Shiryaev, A. A.; Tendeloo, Gustaaf Van

doi:10.1002/smll.200901587

Cited by 112 publications

(105 citation statements)

References 34 publications

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“…For example, theoretical calculations of the crystal energy budget favour the location of nitrogen on the surface rather than in the core, which seems to explain the limited observation of NV centres in chemical vapour deposition and high-pressure high-temperature grains of less than 40 nm in size 11,12 , and favours the prediction that nanodiamonds smaller than 10 nm in size do not contain NV centres 7,13 . Although sub-10-nm nanodiamonds with NV centres have been produced using a top-down approach (milling luminescent high-pressure hightemperature microdiamonds into 7-nm particles 6,14 ), the question of NV stability in isolated detonation nanodiamonds persists.…”

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confidence: 95%

Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds

et al. 2010

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Nitrogen-vacancy colour centres in diamond can undergo strong, spin-sensitive optical transitions under ambient conditions, which makes them attractive for applications in quantum optics 1 , nanoscale magnetometry 2,3 and biolabelling 4 . Although nitrogen-vacancy centres have been observed in aggregated detonation nanodiamonds 5 and milled nanodiamonds 6 , they have not been observed in very small isolated nanodiamonds 7 . Here, we report the first direct observation of nitrogen-vacancy centres in discrete 5-nm nanodiamonds at room temperature, including evidence for intermittency in the luminescence (blinking) from the nanodiamonds. We also show that it is possible to control this blinking by modifying the surface of the nanodiamonds.Detonation nanodiamond is routinely produced on an industrial scale, and the raw material can be disintegrated into a stable 5-nm monodisperse colloid 8 . The combination of inert core and chemically reactive surface, which can host a variety of moieties, is appealing for chemists, biologists and material scientists 9,10 . Quantum magnetometry 2,3 is an example of an emerging technology that will directly benefit from the availability of nanocrystals with welldefined sizes in the 5-nm range, because the sensitivity to single spins is inversely proportional to the cube of the distance between the sensor (that is, the nitrogen-vacancy (NV) centre) and the spin being detected.Producing and detecting NV colour centres in isolated 5-nm detonation nanodiamond has been controversial, and there has been some scepticism regarding their stability as a useful emitter in a discrete crystal. For example, theoretical calculations of the crystal energy budget favour the location of nitrogen on the surface rather than in the core, which seems to explain the limited observation of NV centres in chemical vapour deposition and high-pressure high-temperature grains of less than 40 nm in size 11,12 , and favours the prediction that nanodiamonds smaller than 10 nm in size do not contain NV centres 7,13 . Although sub-10-nm nanodiamonds with NV centres have been produced using a top-down approach (milling luminescent high-pressure hightemperature microdiamonds into 7-nm particles 6,14 ), the question of NV stability in isolated detonation nanodiamonds persists.In aggregated detonation nanodiamonds (agglomerates and agglutinates 8 ), high-sensitivity, time-gated luminescence and electronic paramagnetic resonance spectroscopy have been used to extract a weak NV signal from a strong luminescence background 5 . The experiments highlight the eclipsing nature of the graphitic surface layers in nanodiamond aggregates-NV centres were simply not visible through the broadband luminescence from the surface and grain boundary material. To distinguish the NV spectral signature from the large grain boundary luminescence overhead, diamond synthesis yielding discrete sub-10-nm detonation nanodiamonds is vital. Here, we use a robust deaggregation and dispersion method, which diminishes the crystal-crystal interaction to...

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Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds

et al. 2010

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“…2.1). Similarly to bulk diamond, these chemical impurities are preferentially trapped onto structural defects, as shown for nitrogen by electron energy loss spectroscopy (EELS) [55] and aberration-corrected transmission electron microscopy [56]. On the contrary, NDs produced from HPHT diamond exhibit less structural defects in their diamond core.…”

Section: Defects In Diamond Corementioning

confidence: 98%

Nanodiamonds: From Synthesis and Purification to Deposition Techniques, Hybrids Fabrication and Applications

Arnault

2016

Carbon Nanoparticles and Nanostructures

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The present chapter summarizes the recent advances in the production and the purification methods of nanodiamonds. The different strategies for seeding and patterning of surfaces are detailed. First reports of hybrids based on nanodiamonds are included like core shell particles or decoration with carbon dots or metallic atoms. Finally, an overview of applications for composites and nanomedicine is provided.

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“…51 For many years, all available data pointed to a strong dependence on crystal size and the surface-tovolume ratio, and the optical emission from such defects was rarely seen in small diamond nanoparticles (o40 nm in diameter). 52,54 Photo-physical characteristics for 25 nm particles were later reported, 54 and most recently N-V emission from 5 nm detonation nanodiamond agglomerates 55 and isolated 8 nm diamonds 56 has been shown.…”

Section: Photoactive N-v Centresmentioning

confidence: 98%

Distribution, Diffusion and Concentration of Defects in Colloidal Diamond

Barnard

2014

Nanodiamond

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The family of carbon nanomaterials is a rich and exciting area of research that spans materials science, engineering, physics, and chemistry; and most recently, is having an impact in biology and medicine. However, spontaneous, inefficient (reversible and irreversible) phase transformations prevail at small sizes, and most (in the absence of stable surface passivation) diamond nanomaterials are decorated with a full or partial fullerenic outer shell. Although imperfect, these hybrid sp2/sp3 core–shell particles have been shown to exhibit some useful properties, particularly when combined with other imperfections, such as functional point defects. Among the variety of point defects found in diamond nanoparticles, the GR1, N-V, H3, and N3 defects emit strong and stable luminescence in the visible range. These optical properties can be harnessed for a variety of applications, provided that the structural integrity of the host nanodiamond can be assured. This chapter reviews a number of complementary computational studies examining the stability of point defects in colloidal diamond particles as a function of the radial distribution and types of surface chemistry. This data is used to predict the relative concentrations that may be expected at different sizes.

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Nitrogen and Luminescent Nitrogen‐Vacancy Defects in Detonation Nanodiamond

Cited by 112 publications

References 34 publications

Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds

Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds

Nanodiamonds: From Synthesis and Purification to Deposition Techniques, Hybrids Fabrication and Applications

Distribution, Diffusion and Concentration of Defects in Colloidal Diamond

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