Inga A. Dobrinets scite author profile

Diamond-based p-i-n light-emitting diodes capable of single-photon emission in the visible spectral region at room temperature are discussed. The diodes were fabricated on a high quality single crystal diamond grown by chemical vapor deposition. Implantation of boron and phosphorus ions followed by annealing at a temperature of 1600 °C has been used for doping p-type and n-type areas, respectively. Electrical characterization of the devices demonstrates clear diode behavior. Spectra of electroluminescence generated in the i-area reveal sole emission from the neutral nitrogen-vacancy (NV) defects. Photon antibunching implies single-photon character of this emission when generated by individual NV defects.

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Passive charge state control of nitrogen‐vacancy centres in diamond using phosphorous and boron doping

Groot-Berning

Raatz

Dobrinets

et al. 2014

Physica Status Solidi (a)

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341 97 32748The control and stabilisation of the charge state of nitrogenvacancy centres in diamond is an important issue for the achievement of reliable processing of spin-based quantum information. The effect of phosphorous and boron doping of diamond on the charge state of nitrogen-vacancy (NV) centres is shown here. Ensembles of NV centres are produced at a depth of 60 nm in ultrapure diamond by implantation of nitrogen ions. Overlapping with the NV ensembles, donor and acceptor doped regions of different doping levels are prepared by ion implantation of phosphorus and boron followed by annealing in vacuum at 1500 8C. We show how the charge state of NV centres is controlled by the presence of phosphorous or boron atoms in their neighbourhood. For the lowest doping level, spectral measurements on the ensemble of NV centres reveal a higher amount of NV 0 in the case of boron and a higher amount of NV À in the case of phosphorus, as compared with undoped regions. This behaviour is strengthened when the doping level is increased. Interestingly, the charge state control of native silicon-vacancy centres is also evidenced. Finally, we discuss the role of the surface termination of diamond on the average charge state of the NV ensemble (still dominant even at a depth of 60 nm) and confirm that the surface 2D-hole-gas (H-termination) can be compensated by nitrogen itself.

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Carbon nanodots made on diamond surface by focused ion beam

Зайцев¹,

Dobrinets²

2006

Physica Status Solidi (a)

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Inga A. Dobrinets

HPHT-Treated Diamonds

Diamond based light-emitting diode for visible single-photon emission at room temperature

Passive charge state control of nitrogen‐vacancy centres in diamond using phosphorous and boron doping

Carbon nanodots made on diamond surface by focused ion beam

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