Statistical investigations on nitrogen-vacancy center creation

Antonov, D., Häußermann, T., Aird, A., Roth, J., Trebin, H.-R., Müller, C., McGuinness, L., Jelezko, F., Yamamoto, T., Isoya, J., Pezzagna, S., Meijer, Jan Berend, Wrachtrup, J.

15 August 2018

Quantum information technologies require networks of interacting defect bits. Color centers, especially the nitrogen vacancy (NV-) center in diamond, represent one promising avenue, toward the realisation of such devices. The most successful technique for creating NV- in diamond is ion implantation followed by annealing. Previous experiments have shown that shallow nitrogen implantation (<10 keV) results in NV- centers with a yield of 0.01%–0.1%. We investigate the influence of channeling effects during shallow implantation and statistical diffusion of vacancies using molecular dynamics and Monte Carlo simulation techniques. Energy barriers for the diffusion process were calculated using density functional theory. Our simulations show that 25% of the implanted nitrogens form a NV center, which is in good agreement with our experimental findings.

nitrogen vacancy, NV

info:eu-repo/classification/ddc/530

ddc:530

Quantum Sensing with NV Centers in Diamond

Kavatamane Rathnakara, Vinaya Kumar

27 September 2019

No description available.

530

Physik (PPN621336750)

Nitrogen Vacancy (NV) Center in Diamond

Giant magneto-impedance (GMI)

Quantum sensing

Liquid Crystals

Wide bandwidth instantaneous radio frequency spectrum analyzer based on nitrogen vacancy centers in diamond

Chipaux, M., Toraille, L., Larat, C., Morvan, L., Pezzagna, S., Meijer, Jan Berend, Debuisschert, T.

15 August 2018

We propose an original analog method to perform instantaneous and quantitative spectral analysis of microwave signals. An ensemble of nitrogen-vacancy (NV) centers held in a diamond plate is pumped by a 532 nm laser. Its photoluminescence is imaged through an optical microscope and monitored by a digital camera. An incoming microwave signal is converted into a microwave field in the area of the NV centers by a loop shaped antenna. The resonances induced by the magnetic component of that field are detected through a decrease of the NV centers photoluminescence. A magnetic field gradient induces a Zeeman shift of the resonances and transforms the frequency information into spatial information, which allows for the simultaneous analysis of the microwave signal in the entire frequency bandwidth of the device. The time dependent spectral analysis of an amplitude modulated microwave signal is demonstrated over a bandwidth of 600 MHz, associated to a frequency resolution of 7MHz , and a refresh rate of 4 ms. With such integration time, a field of a few hundreds of lW can be detected. Since the optical properties of NV centers can be maintained even in high magnetic field, we estimate that an optimized device could allow frequency analysis in a range of 30 GHz, only limited by the amplitude of the magnetic field gradient. In addition, an increase of the NV centers quantity could lead both to an increase of the microwave sensitivity and to a decrease of the minimum refresh rate down to a few ls.

info:eu-repo/classification/ddc/530

ddc:530