Heterodyne detection of radio-frequency electric fields using point defects in silicon carbide
Gary Wolfowicz, Christopher P. Anderson, Samuel J. Whiteley, David D., Awschalom

TL;DR
This paper demonstrates a novel heterodyne detection method using point defects in silicon carbide for highly sensitive, high-resolution radio-frequency electric field sensing, enabling both incoherent and coherent measurements with vector capabilities.
Contribution
It introduces a heterodyne detection technique that overcomes previous limitations, enhancing sensitivity, spatial resolution, and dynamic range in defect-based electric field sensing.
Findings
Detection sensitivity as low as 1.1 (V/cm)/√Hz
Near-diffraction limited spatial resolution
Ability to perform in-plane vector electric field measurements
Abstract
Sensing electric fields with high sensitivity, high spatial resolution and at radio frequencies can be challenging to realize. Recently, point defects in silicon carbide have shown their ability to measure local electric fields by optical charge conversion of their charge state. Here we report the combination of heterodyne detection with charge-based electric field sensing, solving many of the previous limitations of this technique. Owing to the non-linear response of the charge conversion to electric fields, the application of a separate "pump" electric field results in a detection sensitivity as low as 1.1 (V/cm)/, with near-diffraction limited spatial resolution and tunable control of the sensor dynamic range. In addition, we show both incoherent and coherent heterodyne detection, allowing measurements of either unknown random fields or synchronized fields with higher…
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