Your search keyword '"Pavel G. Baranov"' showing total 2 results

1. Multi-photon multi-quantum transitions in the spin-3/2 silicon-vacancy centers of SiC

Author

Harpreet Singh, Mario Alex Hollberg, Andrey N. Anisimov, Pavel G. Baranov, and Dieter Suter

Subjects

Physics, QC1-999

Abstract

Silicon vacancy centers in silicon carbide are promising candidates for storing and manipulating quantum information. Implementation of fast quantum gates is an essential requirement for quantum information processing. In a low magnetic field, the resonance frequencies of silicon vacancy spins are in the range of a few MHz, the same order of magnitude as the Rabi frequencies of typical control fields. As a consequence, the rotating wave approximation becomes invalid and nonlinear processes like the absorption and emission of multiple photons become relevant. This paper focuses on multi-photon transitions of negatively charged silicon vacancies driven by a strong RF field. We present continuous-wave optically detected magnetic resonance (ODMR) spectra measured at different RF powers to identify the 1-, 2-, and 3 RF photon transitions of different types of the silicon vacancy in the 6H-SIC polytype. Time-resolved experiments of Rabi oscillations and free induction decays of these multiple RF photon transitions were observed. Apart from zero-field data, we also present spectra in magnetic fields with different strength and orientation with respect to the system's symmetry axis.

Published

2022

2. Zero-Field ODMR and relaxation of Si-vacancy centers in 6H-SiC

Author

Harpreet Singh, Andrey N Anisimov, Pavel G Baranov, and Dieter Suter

Subjects

silicon vacancy, silicon carbide, ODMR, temperature dependend ODMR, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

Silicon vacancies in silicon carbide (SiC) have been proposed as interesting candidates for quantum technology applications such as quantum sensing and quantum repeaters. SiC exists in many polytypes with different plane stacking sequences, and in each polytype, the vacancies can occupy a variety of different lattice sites. In this work, we focus on the three important charged silicon vacancies in the 6 H -SiC polytype. We record the photoluminescence and continuous-wave optically detected magnetic resonance (ODMR) spectra at different radio-frequency power levels and different temperatures. We individually select the zero-phonon lines of the different silicon vacancies at low temperatures and record the corresponding ODMR spectra. ODMR allows us to correlate optical and magnetic resonance spectra and thereby separate signals from V _1 and V _3 . The results also explain the observed sign change of the ODMR signal as a function of temperature.

Published

2023