Robust quantification of the diamond nitrogen-vacancy center charge state via photoluminescence spectroscopy

TL;DR

This paper introduces a robust, quantitative method for determining the charge state ratios of nitrogen-vacancy centers in diamond using photoluminescence spectroscopy with dual excitation, applicable across various sample types and setups.

Contribution

The authors develop a dual excitation protocol that accurately quantifies NV charge states using reference spectra, improving consistency over previous qualitative methods.

Findings

DEP yields consistent charge state ratios across samples

Results agree with NV photophysics understanding

Method outperforms previous techniques in robustness

Abstract

Nitrogen vacancy (NV) centers in diamond are at the heart of many emerging quantum technologies, all of which require control over the NV charge state. Hence, methods for quantification of the relative photoluminescence (PL) intensities of the NV$^0$ and NV$^-$ charge state, i.e., a charge state ratio, are vital. Several approaches to quantify NV charge state ratios have been reported but are either limited to bulk-like NV diamond samples or yield qualitative results. We propose an NV charge state quantification protocol based on the determination of sample- and experimental setup-specific NV$^0$ and NV$^-$ reference spectra. The approach employs blue (400-470 nm) and green (480-570 nm) excitation to infer pure NV$^0$ and NV$^-$ spectra, which are then used to quantify NV charge state ratios in subsequent experiments via least squares fitting. We test our dual excitation protocol (DEP) for a bulk diamond NV sample, 20 and 100 nm nanodiamond particles and compare results with those obtained via other commonly used techniques such as zero-phonon line fitting and non-negative matrix factorization. We find that DEP can be employed across different samples and experimental setups and yields consistent and quantitative results for NV charge state ratios that are in agreement with our understanding of NV photophysics. By providing robust NV charge state quantification across sample types and measurement platforms, DEP will support the development of NV-based quantum technologies.