Magnetic field-assisted spectral decomposition and imaging of charge states of NV centers in diamond

Abstract

With the advent of quantum technology, nitrogen vacancy (NV) centers in diamond turn out to be a frontier which provides an efficient platform for quantum computation, communication and sensing applications. Due to the coupled spin-charge dynamics of the NV system, knowledge about NV charge state dynamics can help to formulate efficient spin control sequences strategically. Through this paper we report two spectroscopy-based deconvolution methods to create charge state mapping images of ensembles of NV centers in diamond. First, relying on the fact that an off axis external magnetic field mixes the electronic spins and selectively modifies the photoluminescence (PL) of NV-, we perform decomposition of the optical spectrum for an ensemble of NVs and extract the spectra for NV- and NV0 states. Next, we introduce an optical filter based decomposition protocol and perform PL imaging for NV- and NV0. Earlier obtained spectra for NV- and NV0 states are used to calculate their transmissivities through a long pass optical filter. These results help us to determine the spatial distribution of the NV charge states in a diamond sample.