Related papers: Pulsed Vector Atomic Magnetometer Using an Alternating Fast-Rotating Field

Pulsed Vector Atomic Magnetometer Using an Alternating Fast-Rotating Field

URL: http://arxiv.org/abs/2304.00214v4
Date: Thu, 06 Feb 2025 09:16:45 GMT
Title: Pulsed Vector Atomic Magnetometer Using an Alternating Fast-Rotating Field
Authors: Tao Wang, Wonjae Lee, Mark Limes, Tom Kornack, Elizabeth Foley, Michael Romalis,
Abstract summary: We introduce a vector atomic magnetometer that employs a fast-rotating magnetic field applied to a pulsed $87$Rb scalar atomic magnetometer. operating in gradiometer mode, the magnetometer achieves a total field gradient sensitivity of 35 $mathrmfT/sqrtHz$ (0.7 parts per billion) and angular resolutions of 6 $mathrmnrad/sqrtHz$ at a 50 $mu$T Earth field strength.
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Abstract: We introduce a vector atomic magnetometer that employs a fast-rotating magnetic field applied to a pulsed $^{87}$Rb scalar atomic magnetometer. This approach enables simultaneous measurements of the total magnetic field and its two polar angles relative to the rotation plane. Operating in gradiometer mode, the magnetometer achieves a total field gradient sensitivity of 35 $\mathrm{fT/\sqrt{Hz}}$ (0.7 parts per billion) and angular resolutions of 6 $\mathrm{nrad/\sqrt{Hz}}$ at a 50 $\mu$T Earth field strength. The noise spectra remain flat down to 1 Hz and 0.1 Hz, respectively. Here we show that this method overcomes several metrological challenges commonly faced by vector magnetometers and gradiometers. We propose a unique peak-altering modulation technique to mitigate systematic effects, including a newly identified dynamic heading error. Additionally, we establish the fundamental sensitivity limits of the sensor, demonstrating that its vector sensitivity approaches scalar sensitivity while preserving the inherent accuracy and calibration benefits of scalar sensors. This high-dynamic-range, ultrahigh-resolution magnetometer offers exceptional versatility for diverse applications.

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