What question did this study set out to answer?

The aim is to explore the resolution limit of Fourier magnetic imaging for nitrogen-vacancy centers in diamond.

June 6, 2026

Fourier magnetic imaging of nitrogen-vacancy center with sub-nanometer pixel resolution

Key Points

The aim is to explore the resolution limit of Fourier magnetic imaging for nitrogen-vacancy centers in diamond.
Developed a compact experimental platform for Fourier magnetic imaging under ambient conditions.
Achieved a pulsed magnetic field gradient of 13.5 G/μm to improve imaging precision.
Implemented thermal drift compensation to enhance localization accuracy.
Localized a single nitrogen-vacancy center with a pixel resolution of 0.69 nm.
Measured a magnetic field deviation of 9 nT, demonstrating precision in imaging.
Showed potential applications for localizing spins within proteins and cells.

Abstract

Solid-state spins in diamond are promising building blocks for quantum computing and quantum sensing, both of which require precise nanoscale addressing of individual spins. To explore the resolution limit of this approach, we demonstrate Fourier magnetic imaging of nitrogen-vacancy (NV) centers in diamond under state-of-the-art conditions. We constructed a highly compact experimental platform featuring thermal drift compensation under ambient conditions and generated a pulsed magnetic field gradient of up to 13.5 G/μm. By implementing the Fourier magnetic imaging protocol, we achieved localization of a single NV center with a pixel resolution of 0.69 nm and a magnetic field measurement deviation of 9 nT. This technique holds potential for applications such as localizing spins within proteins and cells.

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Cite This Study

Lei et al. (Mon,) studied this question.

synapsesocial.com/papers/6a23bb2071a5da9775e76aa4 https://doi.org/https://doi.org/10.1063/5.0325126

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