# Narrow-bandwidth sensing of high-frequency fields with continuous   dynamical decoupling

**Authors:** Alexander Stark, Nati Aharon, Thomas Unden, Daniel Louzon, Alexander, Huck, Alex Retzker, Ulrik Lund Andersen, Fedor Jelezko

arXiv: 1706.04779 · 2017-11-15

## TL;DR

This paper introduces a method to extend high sensitivity magnetic field sensing to high frequencies using continuous dynamical decoupling, demonstrated with nitrogen-vacancy centers in diamond, achieving detection at 1.6 GHz.

## Contribution

The authors develop a general scheme integrating dynamical decoupling into high-frequency sensing, extending low-frequency techniques to the GHz range.

## Key findings

- Achieved coherence times up to 1.43 ms in diamond NV centers.
- Detected magnetic fields as weak as 4 nT at 1.6 GHz.
- Observed increased coherence time due to the signal itself.

## Abstract

State-of-the-art methods for sensing weak AC fields are only efficient in the low frequency domain (< 10 MHz). The inefficiency of sensing high frequency signals is due to the lack of ability to use dynamical decoupling. In this paper we show that dynamical decoupling can be incorporated into high frequency sensing schemes and by this we demonstrate that the high sensitivity achieved for low frequency can be extended to the whole spectrum. While our scheme is general and suitable to a variety of atomic and solid-state systems, we experimentally demonstrate it with the nitrogen-vacancy center in diamond. For a diamond with natural abundance of $^{13}$C we achieve coherence times up to 1.43 ms resulting in a smallest detectable magnetic field strength of 4 nT at 1.6 GHz. Attributed to the inherent nature of our scheme, we observe an additional increase in coherence time due to the signal itself.

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1706.04779/full.md

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Source: https://tomesphere.com/paper/1706.04779