# Sub-millihertz magnetic spectroscopy with a nanoscale quantum sensor

**Authors:** Simon Schmitt, Tuvia Gefen, Felix M. St\"urner, Thomas Unden, Gerhard, Wolff, Christoph M\"uller, Jochen Scheuer, Boris Naydenov, Matthew Markham,, Sebastien Pezzagna, Jan Meijer, Ilai Schwarz, Martin Plenio, Alex Retzker,, Liam P. McGuinness, Fedor Jelezko

arXiv: 1706.02103 · 2017-06-08

## TL;DR

This paper introduces a quantum sensing protocol that surpasses the sensor's coherence time, achieving ultra-narrow linewidth magnetic field measurements at the nanoscale with unprecedented frequency resolution.

## Contribution

The authors demonstrate a novel quantum sensing method that extends spectral precision beyond the qubit coherence time using a classical clock as a stability reference.

## Key findings

- Achieved a frequency resolution of 607 μHz in nanoscale magnetic sensing.
- Demonstrated spectral precision scaling as T^{-3/2} in time.
- Narrow linewidth magnetometer with 8 orders of magnitude improvement over qubit coherence time.

## Abstract

Precise timekeeping is critical to metrology, forming the basis by which standards of time, length and fundamental constants are determined. Stable clocks are particularly valuable in spectroscopy as they define the ultimate frequency precision that can be reached. In quantum metrology, where the phase of a qubit is used to detect external fields, the clock stability is defined by the qubit coherence time, which determines the spectral linewidth and frequency precision. Here we demonstrate a quantum sensing protocol where the spectral precision goes beyond the sensor coherence time and is limited by the stability of a classical clock. Using this technique, we observe a precision in frequency estimation scaling in time $T$, as $T^{-3/2}$ for classical oscillating fields. The narrow linewidth magnetometer based on single spins in diamond is used to sense nanoscale magnetic fields with an intrinsic frequency resolution of 607 $\mu$Hz, 8 orders of magnitude narrower than the qubit coherence time.

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Source: https://tomesphere.com/paper/1706.02103