Charge state equilibration of nitrogen-vacancy center ensembles in diamond: The role of electron tunneling

TL;DR

This study investigates the charge state equilibration of NV centers in diamond, revealing that electron tunneling, rather than thermal processes, governs charge recovery dynamics, with implications for quantum sensing applications.

Contribution

The paper demonstrates that electron tunneling is the primary mechanism for charge state equilibration in NV centers, supported by experimental pump-probe spectroscopy and density-functional calculations.

Findings

Recovery rate depends on nitrogen donor concentration

No temperature dependence observed in charge recovery

Electron tunneling explains charge state dynamics

Abstract

The charge state stability of nitrogen-vacancy (NV) centers critically affects their application as quantum sensors and qubits. Understanding charge state conversion and equilibration is critical not only for NV centers in diamond but also for defects and impurities in wide-bandgap materials in general. The mechanisms by which these centers change charge state upon optical or electronic excitation without the presence of mobile carriers remain unclear, potentially affecting the performance of applications ranging from phosphors to power electronics. Here, we elucidate this issue for the case of photoionization of NV center ensembles. Using pump-probe spectroscopy, we ionize negatively charged NV centers and monitor the recovery of $\NVm$ on timescales of up to several seconds. We find that the recovery rate depends strongly on the concentration of surrounding nitrogen donors. Remarkably, the equilibration dynamics exhibit no discernible dependence on temperature, ruling out thermally activated processes. The multiphonon-assisted electron tunneling model, supported by density-functional calculations, explains the measurements and identifies tunneling as the equilibration mechanism.