Nonlinear optical charge state switching and pumping to a diamond NV center dark state
Abstract
The photodynamics of diamond nitrogen-vacancy (NV) centers limits their performance in many quantum technologies. Quenching of photoluminescence, which degrades NV readout, is commonly ascribed to a dark state that is not fully understood. Using a nanoscale cavity to generate intense infrared fields that quench NV emission nonlinearly with field intensity, we show that the dark state is accessed by two-photon pumping into the 4\!A2 quartet state of the neutrally charged NV (NV0). We constrain this state's energy relative to the NV0 ground-state (2\!E) to <0.58\,eV and the recombination energy threshold to the NV- ground state (3\!A2) to ≤2.33\,eV. Furthermore, we estimate the intrinsic lifetime of 4\!A2 state to be 1.78-6.06\,μs and show that accessing this state allows sensing of local infrared fields. This new understanding will allow predictions of the limits of NV technologies reliant upon intense fields, including levitated systems, spin--optomechanical devices, and absorption--based magnetometers.
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