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Workshop on optically-pumped magnetometers - WOPM2025
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WHGA/001 - Auditorium (PSI)
WHGA/001 - Auditorium
PSI
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Description
The 13th workshop on optically-pumped magnetometers focuses on the magnetometers, their performance and their application in various areas. It is organized by the ultracold neutron physics group and the laboratory for particle physics..
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WOPM2025
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Vector magnetometers provide lots of information for applications that require analysis of magnetic source ranging from bio-imaging to geophysical exploration. Magnetometer based on nitrogen-vacancy (NV) centers in diamond, as an unprecedented combination of spatial resolution and magnetic sensitivity, however, normally need complex manipulation to distinguish the correspondence between field projections and NV axes1, or even unable to measure certain field directions[2]. We developed an omnidirectional vector magnetometry which combines precise measurements of full NV axes by few applications of magnetic fields, and logical solving the correspondence and readout of overlapped resonance frequencies by selectively magnetic manipulating NV ensembles, ensuring a good detection accuracy in all directional detections. This method is not only intelligent and convenient, but also capable of measuring dead zones due to overlapping. With conventional laboratory setup and commercial NV samples, we achieved an angular resolution around 0.02˚ in all direction of magnetic field and an angular error around 0.2˚. The angular resolution is expected to reach arc seconds by optimization of experimental conditions. This method can improve the universality and practicality of NV magnetometers, and promote the development of NV towards industrial magnetometers.
1 T. Weggler, C. Ganslmayer, F. Frank, T. Eilert et al., “Determination of the three-dimensional magnetic field vector orientation with nitrogen vacancy centers in diamond,” Nano Letters, vol. 20, no. 5, pp. 2980–2985,2020.
[2] P. Reuschel, M. Agio, and A. M. Flatae, “Vector magnetometry based on polarimetric optically detected magnetic resonance,” Advanced Quantum Technologies, vol. 5, no. 11, p. 2200077, 2022Speaker: Ms Zhiyin Sun (School of Electrical Engineering and Automation, Harbin institue of technology)
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Anti-relaxation coating (ARC) vapor cells are a critical component in atomic physics and quantum sensing, yet their widespread adoption is hindered by short spin coherence times and low manufacturing yields, stemming from the lack of systematic preparation protocols. Herein, we present an in-situ monitoring system that enables real-time optimization of the spin coherence time and vapor density during the ARC vapor cell preparation. By integrating real-time process monitoring and closed-loop feedback control into the empirical cell-curing method, our system dynamically adjusts the curing parameters to optimize the spin coherence time to second-scale. The proposed system improves the manufacturing yield of ARC vapor cells and provides a foundational platform for the advancement of quantum sensors.
(a) Schematic of the experimental device. (b) The structure of the oven. (c) Characterization indices of vapor cells manufactured with three methods. The $T_1$ and $n$ of three batches of vapor cells are marked in blue, green and red, which is uncured, empirical cured and in-situ cured, respectively. The black dotted line is the requirement curve, presenting the constant product of $T_1$ and $n$, corresponding to limit of $\delta B_{\text{SNL}}$ of femtotesla level.
Speaker: Wentian Xiang (Peking University)
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Optically-pumped magnetometers (OPM) using metastable helium-4 species allow real-time, space-resolved vector measurement of magnetic fields at room temperature. Moreover, the bandwidth of this kind of sensors --up to 2 kHz-- covers the whole emission of the human brain. Hence, this technology proves very promising for magnetoencephalography (MEG) applications while minimizing patient discomfort caused by excessive heating or cooling of the sensors 1. Although the signal-to-noise ratios in field recordings already match the ones of SQUID systems [2], we continue the efforts to improve the intrinsic noise of these OPMs [3].
In this sense, we started by characterizing its sources. They include the phenomena in the plasma discharge --necessary to produce the metastable atoms-- and the noises from the laser --that optically pumps the metastable atoms. We present measurements of the noises originated from both these sources and demonstrate their respective contributions to the total intrinsic noise of the sensor. Ways for improving the signal-to-noise ratio of our technology are also discussed.
References
1 W. Fourcault et al., Optics Express 29, 14467 (2021)
[2] J.-M. Badier et al., eNeuro. 2023 Dec 22, 10(12)
[3] M. Bonnet et al., Front. Med. Technol. 7 (2025)Speaker: Agustin Palacios-Laloy (MAG4Health)
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Optically pumped magnetometers (OPMs) offer significant advantages for biomagnetic measurements such as magnetoencephalography (MEG), owing to their high sensitivity, room-temperature operation, and potential for wearable configurations. In these applications, gradiometric measurement serves as an effective method to suppress common-mode environmental noise. However, it is difficult to make the two channels in a gradiometer perform identically, and precisely adjusting system parameters remains a challenge, which limits the common-mode rejection ratio (CMRR).
To overcome this limitation, we propose a method to improve the CMRR of OPM gradiometers, based on analyzing and controlling the phase-frequency response differences between the two channels. The phase differences between the two channels would degrade the CMRR, as they reduce the consistency of the responses. We model the relationship between the phase-frequency response of the gradiometer and the relaxation rate of the cell and the remanence along the pump axis. This model reveals a phase intersection point at which phase responses between two channels are aligned, leading to the enhanced CMRR. By precisely adjusting the magnetic field along the pump axis, this intersection point can be controlled, thereby enabling optimization of the frequency band in which maximum CMRR is achieved. As a result, the average CMRR within 1-50 Hz frequency band is improved by more than one order of magnitude, exceeding 2000. This method enables efficient performance enhancement without additional components and offers flexibility for various application scenarios.
Speaker: Yujian Ma (Beihang University) -
Sensitivity Improvement of a $^4$He Optically Pumped Magnetometer in the RF band
N. Umetani$^{1}$, Y. Fujimoto$^1$, K. Shinada$^1$, J. Saikawa$^1$, T. Munaka$^1$, and T. Kobayashi$^2$
$^1$Technology Research Laboratory, Shimadzu Corporation, Soraku-gun, Kyoto, Japan*
$^2$HBRC, Graduate School of Medicine, Kyoto University, Sakyo-ku, Kyoto, Japan***High-sensitivity detection of radio-frequency (RF) magnetic fields is critical for various applications, from radio communication to fundamental physics experiments. Ultra-low field MRI (ULF-MRI) with the static magnetic field less than 10 mT, in particular, demands sensors capable of operating with high sensitivity in the 100 kHz to 400 kHz range 1. Optically pumped magnetometers (OPMs) are promising candidates for high-sensitivity RF magnetic field detection. Previous studies have shown that the OPMs using alkali metal atoms exhibit high sensitivity for RF magnetic field detection, but their operation typically requires heating and careful management of spin-exchange relaxation in static magnetic fields [2]. Our research focuses on OPM using $^4$He ($^4$He-OPM), which operates without heating and offers a broad frequency range. While our previous work achieved a noise floor of 90 fT/Hz$^{1/2}$ at 100 kHz, sensitivity decreased at higher frequencies [3]. In this study, through adjustments in the magnetic field configuration, we improved the sensitivity of $^4$He-OPM for higher frequencies. Specifically, we achieved a noise floor of 13 fT/Hz$^{1/2}$ at 300 kHz. In addition, we will show the potential of $^4$He-OPM for high-sensitivity detection at higher frequencies for applications such as ULF-MRI.
Figure 1: (a) Schematic diagram of $^4$He-OPM experimental setup. LD: laser diode; C: collimator; P: polarizer; WP: half-wave plate; PD: photo diode. (b) Amplitude spectral density for 100 pT$_{\rm{rms}}$ sinusoidal signals applied at 300 kHz and 100 kHz.
References
- S. Hori, et al., Journal of Magnetic Resonance 343, 107280 (2022).
- S.-K. Lee et al., Appl. Phys. Lett. 89, 214106 (2006).
- Y. Fujimoto, et al., WOPM Book of Abstracts, p. 27 (2024).
Speaker: Naoki Umetani (Shimadzu Corporation) -
Enhancing the interaction strength between light and atoms amplifies the Faraday rotation effect, thereby improving the measurement sensitivity of optical rotation detection. This work integrates a multi-reflection cavity into the vapor cell of the SERF co-magnetometer for the first time, increasing the interaction strength between light and atoms. We establish a model that accounts for light propagation in multiple directions, clarifying the impact of the sensitive-axis component on the output signal and improving the system's measurement accuracy. Subsequently, we propose a method for calculating the number of reflections within the cavity based on light absorption, which ensures the stable and effective operation of the multi-reflection cavity in the SERF co-magnetometer. Experimental results show that the Faraday rotation effect is enhanced by a factor of 13.6 compared to single-pass, which closely matches the designed 14 reflections, thereby verifying the accuracy of the response model and the reflection count measurement. This study provides a pathway toward improving the sensitivity of SERF co-magnetometers and supports further exploration of applications in fundamental physics.[Phys. Rev. Lett. 130 . 063201(2023),Commun. Phys. 7. 226(2024)]
Speaker: Jie Zheng (School of Instrumentation and Optoelectronic Engineering, Beihang University, Beijing, 100191, China; Hangzhou Innovation Institute, Beihang University, Hangzhou, 310051, Zhejiang, China; Hefei National Laboratory, Hefei, 230088, Anhui, China) -
Recently, Meta Platforms, Inc. reported that brain-machine interfaces (BMIs) based on magnetoencephalography (MEG) can achieve higher accuracy than those based on electroencephalography (EEG)$^1$. Optically pumped magnetometers (OPMs), which have been actively developed for miniaturization and shield-free measurements, offer a promising noninvasive sensing solution for BMIs. In this study, we investigated whether hand movement tasks could be classified using MEG signals measured with OPM modules, with the goal of advancing BMI applications. A participant performed flexion and extension of either the thumb or the little finger inside a magnetic shield while MEG signals were recorded from sensors placed on the scalp. Simultaneously, myomagnetic signals were recorded from sensors on the forearm to determine movement onset. Independent component analysis was applied to extract brain-related components, followed by frequency analysis and principal component analysis (PCA), from which the first two principal components were used. Figure 1 shows the results of linear classification using a support vector machine (SVM), achieving a classification accuracy of approximately 67% for the two motor tasks. Future work will focus on improving classification performance by optimizing sensor position, increasing the number of sensors, and refining signal processing methods to enable classification of a broader range of tasks.
Reference
$^1$ Brain-to-Text Decoding: A Non-invasive Approach via Typing,
https://ai.meta.com/research/publications/brain-to-text-decoding-a-non-invasive-approach-via-typing/Speaker: Yosuke Ito (Kyoto University) -
This study investigates the effects of power broadening on nonlinear magneto-optical rotation (NMOR) magnetometers. As the laser power increases, the interference between two partially resolved transitions of 87Rb induced by velocity-changing collisions can be exacerbated by power broadening, resulting in a reduction
of the rotation rate, and the shift of the optimal laser frequency corresponding to the maximum rotation rate. The theoretical model of NMOR is established using a four-level double 𝛬 scheme, which takes into account power broadening effects, and experimentally studied in a single-beam NMOR magnetometer with a buffer-gas filled cell. The results indicate that the significant enhancement in rotation rate can be achieved by tuning the laser frequency to the optimal detuning based on our model. This study holds considerable importance for the improvement of magnetic field sensitivity in NMOR magnetometers.
Speaker: Zhenglong Lu (Beihang University) -
For SERF atomic magnetometer, photo-elastic modulator (PEM) is a commonly-used optical polarimetry technique to detect the weak angle signal due to its high sensitivity. Magnetic field to be measured can be obtained by demodulating the first-harmonic response signal from the photoelectric detector (PD) based on the modulation frequency of PEM. The optical rotation angle contains essential information including atom number density and transverse polarization, thereby accurate measurement of the optical rotation angle is very important. However, in previous studies, the optical rotation angle cannot be derived directly and quantitatively through the demodulated first harmonic signal. Therefore, we propose an in-situ measurement method of the optical rotation angle based on the dc and second harmonic components with PEM detection in SERF atomic magnetometer. We analyze the condition when a modulated linearly-polarized light can be derived by PEM. Further, we establish the expressions of the demodulated response signals by second-order approximation and verify our method by experiments. Our method does not introduce additional device and could be generally used in analysis of polarization and atom number density distribution. Moreover, our method is completely unaffected by the variation of the probe beam intensity and convenient for optical rotation angle measurement under PEM modulation in general optical systems, including but not limited to SERF magnetometer.
$U=k{{I}_{\text{probe}}}\left[ {{\varphi }^{2}}+\frac{1}{2}{{\alpha }_{\text{m}}}^{2} \right.+2\varphi {{\alpha }_{\text{m}}}\sin \left( 2\pi ft \right)\left. -\frac{1}{2}{{\alpha }_{\text{m}}}^{2}\cos \left( 4\pi ft \right) \right]$
${{\varphi }^{2}}=\frac{{{U}_{\text{dc}}}-{{U}_{2\text{nd}}}}{2{{U}_{2\text{nd}}}}{{\alpha }_{\text{m}}}^{2}$
The optical polarimetry measurement based on PEM in the SERF atomic magnetometer.
Speakers: Mr Yaoguo Wang (Beihang University), Ms Di Zhan (Beihang University) -
Optically pumped magnetometers (OPMs) utilizing entangled spins offer the promise of sensing performance beyond the standard quantum limit (SQL). Unfortunately, realizing this advantage has proven exceedingly difficult. Entangled states are inherently tricky to create and maintain. It is often better to simply use many unentangled atoms rather than entangling far fewer of them. Nevertheless, recent work by the Polzik group has shown promising progress in the generation and utilization of spin-squeezed states in pulsed radiofrequency OPMs that can surpass the SQL (1).
Inspired by this approach, we are developing a scalar OPM that utilizes a similar pulsed interrogation methodology. The key is a stroboscopic interrogation sequence that is pulsed at twice the Larmor frequency to implement a quantum nondemolition (QND) measurement of the spins. To implement squeezing, this method is used to measure the spins both before and after a free evolution period in which the spins interact with external magnetic fields. Conditioning the final uncertainty in magnetic field on information obtained via the pre-interaction measurement can reduce the final uncertainty below the SQL; the spin ensemble has been put into a squeezed state through a process known as conditional squeezing.
This project has two aims: development of a strong theoretical model to explore the underlaying dynamics of the hot vapor cell on which the OPM is based so we may best predict and optimize squeezing performance and building an experimental platform to test these predictions. Based on the foundation laid by the Romalis group(2) , we are working to implement multiple passings of the probe beam through the vapor cell via a collaboration with Opto-Assembly Inc. Such a multi-passed design leads to a much greater effective optical depth experienced by the probe beam, which can greatly improve the SNR of detection that relies on optical Faraday rotation. This reduces the magnetic field uncertainty stemming from photon shot noise in comparison to the spin-projection noise. Since spin-squeezing can improve only the latter, this architecture should help us realize greater benefits from spin-squeezing.
References
(1) W. Zheng et al. “Entanglement-Enhanced Magnetic Induction Tomography”. Phys. Rev. Lett. 130, 203602 – May, 2023
(2) D. Sheng, S.Li, N. Dural, and M.V. Romalis. “Subfemtotesla Scalar Atomic Magnetometry Using Multipass Cells” Phys. Rev. Lett. 110, 160802 –April, 2013.Speaker: Jonathan Dhombridge (Sandia National Laboratories) -
The precision of magnetic field estimation using a scalar-mode optically pumped magnetometer (OPM) is significantly degraded in the presence of environmental magnetic noise. Spatial inhomogeneity in the noise magnetic field reduces the transverse relaxation time, resulting in a shorter, noisier free induction decay (FID) signal. To address this issue, we employ a spin echo technique using a refocusing $\pi$ radio frequency (RF) pulse. This $\pi$ pulse inverts dephased spins, compensating for the spatial inhomogeneity of the noise field, as illustrated in Fig. 1. Unlike conventional methods, where FID signals decay rapidly in highly inhomogeneous fields, the proposed method extends the observable signal duration.
We conducted an experiment with a scalar-mode OPM in an open-door magnetic shield. The resonance frequency of the bias magnetic field was set to approximately 15 kHz, and the gradient magnetic field of the spatially inhomogeneous noise field was approximately 3 µT/m. As shown in Fig. 2, a $\frac{\pi}{2}$ pulse was applied at 0 seconds, followed by a $\pi$ pulse at approximately 1.5 ms. While the FID signal decayed with a time constant of 0.9 ms, the spin echo signal exhibited a longer time constant of 3.0 ms, indicating an extended observation window.
We experimentally confirmed that spin echo signals can be observed even in the presence of spatially inhomogeneous environmental magnetic fields. Future work will investigate the effectiveness of the spin echo technique outside the magnetic shield.
Speaker: Taiga Fukushima (Kyoto university) -
In conventional magnetic field estimation using scalar-mode optically pumped magnetometers (OPMs), the goal is to estimate the frequency of a decaying sine curve that best fits a free induction decay (FID) signal. This approach assumes a constant magnetic field during each FID period, limiting its ability to track the temporal dynamics of fields oscillating at high frequencies.
To overcome this limitation, we propose a statistical magnetic field estimation method using a physics-informed state-space model (Fig. 1). The state equation, governing the temporal evolution of magnetic fields and spins (latent variables), is derived from a temporally discretized Bloch equation. The observation equation, representing the FID signal (observed variable), is based on the magneto-optical effect, assuming the probe beam is applied along the x-axis. Using an extended Kalman filter and Rauch-Tung-Striebel smoother, the time-varying magnetic field can be estimated from an FID signal at its sampling rate.
We conducted a simulation experiment with time-varying magnetic fields oscillating at 10 Hz (600 pT amplitude) and 10 kHz (1 nT amplitude). The proposed method was compared to the conventional fitting approach. Results showed that the proposed method successfully tracked the 10 kHz field’s temporal evolution. For the 10 Hz field, although the proposed method was less accurate than the conventional method, it still captured the slow dynamics. To enhance performance, we plan to reduce noise in FID signals using a differential OPM array.
Speaker: Ryo Kinoshita (Kyoto University) -
Magnetoencephalography (MEG) based on optically pumped magnetometers (OPM-MEG) is a relatively novel method to measure brain activity non-invasively in humans. It offers several advantages over traditional SQUID (superconducting quantum interference device) based MEG and EEG [1-3]. However, its properties, in particular test-retest reliability (stability of measurements in time) and construct validity (agreement of results with established technologies), need to be evaluated to make day-to-day, routine applications possible.
In this quality control study, we investigated the reliability and validity of auditory mismatch negativity (MMN) recordings from a newly installed OPM-MEG system (Cerca Magnetics Limited, Nottingham, UK) utilizing 64 triaxial sensors (QuSpin, Louisville, CO, USA). The auditory MMN is an electrophysiological response to rule violations in auditory input streams [4], which has been interpreted as reflecting the update of a predictive (generative) model of the acoustic environment [5]. We recorded OPM-MEG from 30 healthy volunteers, measured twice within 24-72 hours, using an established auditory MMN paradigm [6]. First, we focused on construct validity and investigated whether OPM-MEG measurements of MMN responses were qualitatively comparable in terms of event-related fields, timing and topography to previous MMN findings of studies using EEG and traditional MEG. Second, we assessed the test-retest reliability (quantified by intra-class correlation coefficients, ICC) of cognitive (MMN) and sensory (auditory M100) evoked fields, comparing the sensor-level response amplitude and latency over the two separate measurement sessions.
The MMN responses recorded with our OPM-MEG setup are in good agreement with previously reported MMN results of EEG and SQUID-based MEG measurements in terms of both timing and topography. For an illustration of the resulted statistical parametric map of the MMN event related radial field, see Figure 1. The qualitative comparison of group-level MMN topographies and timeseries shows excellent consistency across the two measurement sessions. Test-retest reliability analyses indicate moderate reliability for MMN amplitude (ICC=0.50-0.67 for the z-component of the triaxial sensor signal) but poor reliability for latency (ICC=0.00-0.22), in line with previous EEG literature [7]. By contrast, test-retest reliability of the purely sensory M100 auditory evoked fields has been found to be excellent for amplitude (ICC=0.97) and good-to-excellent for latency (ICC=0.84-0.96), confirming the functionality of our setup in the "out-of-the-box" state without further technical optimisation.
References
1. Boto, E. et al., Moving magnetoencephalography towards real-world applications with a wearable system. Nature 555, 657 (2018)
2. Brookes, M.J. et al., Magnetoencephalography with optically pumped magnetometers (OPM-MEG): the next generation of functional neuroimaging. Trends in Neurosciences 45, 621 (2022)
3. Holmes, N. et al., Enabling ambulatory movement in wearable magnetoencephalography with matrix coil active magnetic shielding. NeuroImage 274, 120157 (2023)
4. Näätänen, R. et al., “Primitive intelligence” in the auditory cortex. Trends in Neurosciences 24, 283 (2001)
5. Garrido, M.I., et al., The mismatch negativity: A review of underlying mechanisms. Neurophysiol. Clin. 120, 453 (2009)
6. Weber, L.A. et al., Auditory mismatch responses are differentially sensitive to changes in muscarinic acetylcholine versus dopamine receptor function. eLife 11, e74835 (2022)
7. Wang, J. et al., Test-retest reliability of duration-related and frequency-related mismatch negativity. Neurophysiol. Clin. 51, 541 (2021)
Speaker: Laszlo Demko (1. Translational Neuromodeling Unit, Institute for Biomedical Engineering, University of Zurich & ETH Zurich, Zurich, Switzerland) -
Molecular Dynamics Optimization of Multilayer OTS SAMs Cells for Enhanced Performance in Single Beam SERF Magnetometers
Yi-an XU1,2, Yuhao WANG1,2, Ziqian YUE1,2, Zhuangsheng ZHU1,2
1 School of Instrumentation Science and Opto-electronics Engineering,
Beihang University, Beijing, China
2 Hangzhou Innovation Institute, Beihang University, Hangzhou, ChinaThe development of high-performance octadecyltrichlorosilane (OTS) SAMs is crucial for mitigating alkali-metal spin relaxation and enhancing the sensitivity of spin-exchange relaxation-free (SERF) magnetometers. In this work, we employ molecular dynamics (MD) simulations to investigate the structural, interfacial, and dynamical properties of OTS SAMs, focusing on optimizing their anti-relaxation behavior. By systematically tuning key simulation parameters, including adsorption energy, wettability, and atomic interaction dynamics. Our findings provide a comprehensive framework for the rational design and optimization of OTS SAMs, paving the way for next-generation atomic magnetometers with enhanced stability and prolonged coherence times. Furthermore, we discuss the broader implications of these advancements in quantum sensing and precision measurement applications.
References
(1) Xu Y, Pei H, Cong Y, et al. A non-thermal method to maintain alkali vapor density of anti-relaxation coating cell in spin exchange relaxation-free magnetometer[J]. Measurement, 2025, 242: 115960.Speaker: Yi-an XU (Beihang University) -
Spin-exchange relaxation-free (SERF) comagnetometer is significant in exploring fundamental physics and high-precision inertial sensing. However, traditional continuous measurement based on steady atomic spin polarization limits the suppression of long-term drifts, which is pivotal for inertial navigation and the search for new physics beyond standard model.We propose a SERF comagnetometer based on self-differential measurement mode using reverse-modulated atomic spin polarization for signal enhancement and noise suppression, as is shown in Fig.1(a). We analyze the dynamic evolutions of alkali electron spin and noble-gas nuclear spin under the pulsed left- and right-circularly polarized pumping scheme. To ensure that the comagnetometer operates in self-compensation regime[Phys. Rev. Lett. 130 . 063201(2023)], we reverse the electron spin while keeping the nuclear spin polarization stable by optimizing the modulation period and duty cycle. Through self-differential, the response of the comagnetometer is improved by 2.95 dB and the low-frequency common-mode at 0.1~2 Hz is suppressed by about 6.53 dB. As is shown in Fig.1(b), the sensitivity is improved by 2.7 times to $3.1\times 10^{-6~\circ}/\text{s}/\sqrt{\text{Hz}}$ @1 Hz compared with the traditional continuous measurement mode.
Speaker: Saixin Zhou (1 School of Instrumentation and Optoelectronic Engineering, Beihang University, Beijing, 100191, China; 2 Hefei National Laboratory, Hefei, 230088, Anhui, China) -
The modulated single-beam Spin-Exchange Relaxation-Free (SERF) optically pumped magnetometers (OPMs) hold significant promise for applications in biomagnetic measurements. Achieving the SERF regime requires a high atomic number density, which necessitates a stable thermal control system for the vapor cell. Conventionally, the vapor cell temperature is measured by the platinum resistance sensor. However, its measurements are non-in-situ and sensitive to positioning. In this study, we demonstrate an approach to control the vapor cell temperature by utilizing the ratio of the second harmonic to the DC component of the transmitted light signal as a feedback parameter for closed-loop temperature regulation. This method enables real-time, in-situ temperature control using the OPM’s optical signal, while exhibiting reduced susceptibility to fluctuations in incident light power.
Experimental results as shown in Fig. 1(a) indicate that this ratio-based feedback is less affected by variations in incident light compared to the DC signal feedback alone. We conduct long-term testing under externally applied disturbances, demonstrating the system's stability and robustness, as shown in Fig. 1(b). Taken together, the results in Figs. 1(a) and 1(b) confirm that this thermal control method effectively suppresses the influence of incident light power fluctuations on optical temperature sensing and satisfies the thermal stability requirements of SERF OPMs, with resistance to external disturbances.
Speaker: Yuhao Wang (Beihang University) -
Comagnetometers have enabled significant progress in searches for physics beyond the standard model and inertial navigation, owing to the ability to substantially suppress magnetic noise. We present a novel type of comagnetometer based on the cooperative coherence transfer (CCT) mechanism [Submitted]. The nonreciprocal coupling is introduced to enable optimized transfer energy matching and improve the transfer efficiency. We demonstrate this mechanism in a $^{21}$Ne-Rb-K comagnetometer, yielding a 15-fold enhancement of the magnetic noise suppression effect compared to the conventional self-compensation (SC) regime [Phys. Rev. Lett. 89. 253002 (2002)]. Consequently, an ultrahigh sensitivity of $7.7\times 10^{-7~\circ}/\text{s}/\sqrt{\text{Hz}}$ from 0.2 to 1.0 Hz, equivalent to $8.7\times10^{-24}~\text{eV} /\sqrt{\text{Hz}}$, is achieved, demonstrating the highest energy resolution [Quantum Sci. Technol. 7. 014001 (2022)]. This platform facilitates potential improvements of over 4 orders of magnitude in constraints on dipole-dipole interaction and monopole-dipole interaction, with broad application prospects.
Speaker: Fan Wang -
Optically pumped magnetometers (OPMs) are highly sensitive sensors that can detect minute biomagnetic fields. However, OPM signals are often degraded by ambient magnetic interference and motion artifacts. To address such noisy signals, we apply independent low-rank matrix analysis (ILRMA), a multichannel blind source separation (BSS) method that leverages the low-rank structure of source power spectrograms in the time-frequency domain. Periodic biomagnetic signals, such as cardiac signals, exhibit clear harmonic structures in their power spectrograms (Figs. (a) and (b)), which can be approximated as low-rank matrices. By exploiting the time-frequency and spatial characteristics of sources, ILRMA effectively separates target physiological signals from noisy multichannel OPM signals.
We conducted a magnetocardiography experiment in a magnetically shielded room using an array of four SERF-type OPMs manufactured by Hamamatsu Photonics K.K. To suppress noise from commercial power sources, the signals were filtered with a 0.5–50 Hz band-pass filter. ILRMA was compared to conventional time-domain independent component analysis (ICA) under determined conditions (equal number of sources and channels). With ICA, cardiac QRS complex patterns appeared across multiple estimated sources (two of four shown in Fig. (c)). In contrast, ILRMA successfully separated the cardiac QRS complex signal from periodic noise as distinct sources (Fig. (d)), demonstrating its superior performance for multichannel magnetocardiography with OPMs.
Reference
[1] D. Kitamura, et al. EURASIP J. Adv. Signal Process., vol.2018, no.28 (2018)Speaker: Kuga Uematsu (Kyoto University) -
Optically pumped magnetometers (OPMs) have significantly advanced the field of biomagnetic sensing, particularly in wearable applications such as magnetoencephalography (MEG). Triaxial measurement techniques further enhance the localization accuracy of these systems by capturing full vector information. However, the precision of triaxial OPM measurements is still constrained by two major issues: crosstalk introduced by multiple modulated magnetic fields and interference from low-frequency ambient magnetic field fluctuations.
To address these limitations, we propose a dynamic triaxial magnetic field measurement method that employs a single modulated magnetic field to reduce crosstalk. Additionally, it incorporates a closed-loop control system to suppress low-frequency magnetic field fluctuations under moving experiments. Experimental results demonstrate that the proposed method achieves measurement sensitivities of 20.3, 9.6, and 42.2 fT/Hz$^{1/2}$ along the $x$, $y$, and $z$ axes, respectively. Moreover, the approach reduces scale factor fluctuation by 95.2% and decreases simulated MEG amplitude error by 64.2% under magnetic interference conditions. These improvements not only enhance measurement accuracy but also expand the practical potential of high-density wearable OPM-MEG systems.
Speaker: Tengyue Long (Beihang University)
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