• Optical Instruments
  • Vol. 46, Issue 1, 70 (2024)
Huihui ZHAI, Xiangyu KANG, Yan CAO, Yang LI, Xiangmei DONG, and Xiumin GAO*
Author Affiliations
  • School of Optical-Electrical and Computer Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
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    DOI: 10.3969/j.issn.1005-5630.202302140018 Cite this Article
    Huihui ZHAI, Xiangyu KANG, Yan CAO, Yang LI, Xiangmei DONG, Xiumin GAO. Research progress on detection methods of weak magnetic signal in all-optical atomic magnetometer[J]. Optical Instruments, 2024, 46(1): 70 Copy Citation Text show less
    References

    [1] SNADDEN M, MCGUIRK J, BOUYER P, et al. Measurement of the earth's gravity gradient with an atom interferometer-based gravity gradiometer[J]. Physical Review Letters, 81, 971-974(1998).

    [3] DANG H B, MALOOF A C, ROMALIS M V. Ultrahigh sensitivity magnetic field and magnetization measurements with an atomic magnetometer[J]. Applied Physics Letters, 97, 151110(2010).

    [4] FANG J C, WAN S G, QIN J, et al. A novel Cs-129Xe atomic spin gyroscope with closed-loop Faraday modulation[J]. Review of Scientific Instruments, 84, 083108(2013).

    [6] ALLRED J C, LYMAN R N, KORNACK T W, et al. High-sensitivity atomic magnetometer unaffected by spin-exchange relaxation[J]. Physical Review Letters, 89, 130801(2002).

    [7] DEHMELT H G. Modulation of a light beam by precessing absorbing atoms[J]. Physical Review, 105, 1924-1925(1957).

    [8] BELL W E, BLOOM A L. Optical detection of magnetic resonance in alkali metal vapor[J]. Physical Review, 107, 1559-1565(1957).

    [9] HAPPER W, TANG H. Spin-exchange shift and narrowing of magnetic resonance lines in optically pumped alkali vapors[J]. Physical Review Letters, 31, 273-276(1973).

    [10] BUDKER D, KIMBALL D F, ROCHESTER S M, et al. Sensitive magnetometry based on nonlinear magneto-optical rotation[J]. Physical Review A, 62, 043403(2000).

    [11] KATSOPRINAKIS G, PETROSYAN D, KOMINIS I K. High frequency atomic magnetometer by use of electromagnetically induced transparency[J]. Physical Review Letters, 97, 230801(2006).

    [12] ITO Y, OHNISHI H, KAMADA K, et al. Development of an optically pumped atomic magnetometer using a K-Rb hybrid cell and its application to magnetocardiography[J]. AIP Advances, 2, 032127(2012).

    [13] ITO Y, OHNISHI H, KAMADA K, et al. Effect of spatial homogeneity of spin polarization on magnetic field response of an optically pumped atomic magnetometer using a hybrid cell of K and Rb atoms[J]. IEEE Transactions on Magnetics, 48, 3715-3718(2012).

    [14] PATTON B, ZHIVUN E, HOVDE D, et al. All-optical vector atomic magnetometer[J]. Physical Review Letters, 113, 013001(2014).

    [15] GARTMAN R, GUARRERA V, BEVILACQUA G, et al. Linear and nonlinear coherent coupling in a bell-bloom magnetometer[J]. Physical Review A, 98, 061401(2018).

    [16] LEVY C S, KORNACK T W, MERCIER P P. Bell-bloom magnetometer linearization by intensity modulation cancellation[J]. IEEE Transactions on Instrumentation and Measurement, 69, 883-892(2020).

    [17] RANJBARAN M, TEHRANCHI M M, HAMIDI S M, et al. Relaxation time dependencies of optically detected magnetic resonance harmonics in highly sensitive Mx magnetometers[J]. Journal of Magnetism and Magnetic Materials, 469, 522-530(2019).

    [18] PETRENKO M V, PAZGALEV A S, VERSHOVSKII A K. Single-beam all-optical nonzero-field magnetometric sensor for magnetoencephalography applications[J]. Physical Review Applied, 15, 064072(2021).

    [19] HUNTER D, DYER T E, RIIS E. Accurate optically pumped magnetometer based on ramsey-style interrogation[J]. Optics Letters, 47, 1230-1233(2022).

    [22] DUAN L H, FANG J C, LI R J, et al. Light intensity stabilization based on the second harmonic of the photoelastic modulator detection in the atomic magnetometer[J]. Optics Express, 23, 32481-32489(2015).

    [23] DING Z C, YUAN J, WANG Z G, et al. Optically pumped rubidium atomic magnetometer with elliptically polarized light[J]. Optik, 127, 5270-5273(2016).

    [24] HU Y H, LIU X J, LI Y, et al. An atomic spin precession detection method based on electro-optic modulation in an all-optical K-Rb hybrid atomic magnetometer[J]. Journal of Physics D:Applied Physics, 50, 265001(2017).

    [25] DING Z C, YUAN J, LONG X W. Practical method for transversely measuring the spin polarization of optically pumped alkali atoms[J]. Journal of Physics B:Atomic, Molecular and Optical Physics, 51, 125001(2018).

    [27] YAO H, LI Y, MA D Y, et al. Acousto-optic modulation detection method in an all-optical K-Rb hybrid atomic magnetometer using uniform design method[J]. Optics Express, 26, 28682-28692(2018).

    [28] XING L, ZHAI Y Y, FU Y, et al. Optical rotation detection method based on acousto-optic modulation in an atomic spin co-magnetometer[J]. Measurement Science and Technology, 32, 025112(2021).

    [29] DING Z Y, HAN B C, TANG J J. Single-beam miniaturized atomic magnetometer with square-wave modulation for magnetoencephalography[J]. IEEE Transactions on Instrumentation and Measurement, 70, 4002206(2021).

    [30] LIU X J, LI Y, WU X D, et al. Reflected atomic magnetometer with single beam[J]. IEEE Sensors Journal, 22, 1238-1244(2022).

    [31] MA Y T, CHEN Y, ZHAO L B, et al. Accurate determination of alkali atom density based on zero-field magnetic resonance in a single-beam spin-exchange relaxation-free atomic magnetometer[J]. Measurement Science and Technology, 33, 105003(2022).

    [32] ZHAO B B, TANG J J, YANG H Y, et al. High-sensitivity pump-probe atomic magnetometer based on single fiber-coupled[J]. Optics & Laser Technology, 159, 109025(2023).

    [34] KORNACK T W, SMULLIN S J, LEE S K, et al. A low-noise ferrite magnetic shield[J]. Applied Physics Letters, 90, 223501.1-223501.3(2007).

    [35] ZHOU X H, NEUBAUER F, ZHAO D, et al. Geometric correction of synchronous scanned Operational Modular Imaging Spectrometer II hyperspectral remote sensing images using spatial positioning data of an inertial navigation system[J]. Journal of Applied Remote Sensing, 9, 096078(2015).

    [37] MIZUTANI N, KOBAYASHI T. Magnetic field vector detection in frequency domain with an optically pumped atomic magnetometer[J]. IEEE Transactions on Magnetics, 48, 4096-4099(2012).

    [38] ZHANG H, ZOU S, CHEN X Y. A method for calibrating coil constants by using an atomic spin co-magnetometer[J]. The European Physical Journal D, 70, 203(2016).

    [39] LIU X J, YANG Y H, DING M, et al. Single-fiber sagnac-like interferometer for optical rotation measurement in atomic spin precession detection[J]. Journal of Lightwave Technology, 37, 1317-1324(2019).

    [40] SALASYUK A S, RUDKOVSKAYA A V, DANILOV A P, et al. Generation of a localized microwave magnetic field by coherent phonons in a ferromagnetic nanograting[J]. Physical Review B, 97, 060404(2018).

    [41] LI J D, QUAN W, ZHOU B Q, et al. SERF Atomic Magnetometer-Recent Advances and Applications: A Review[J]. IEEE Sensors Journal, 18, 8198-8207(2018).

    [42] CHEN X Y, ZHANG H, ZOU S. Measurement sensitivity improvement of all-optical atomic spin magnetometer by suppressing noises[J]. Sensors, 16, 896(2016).

    [45] CAI M, WANG S L, GAO B, et al. A new electro-optical switch modulator based on the surface plasmon polaritons of graphene in mid-infrared band[J]. Sensors, 19, 89(2018).

    [46] LIN H F, TIAN Y, TAN B Z, et al. Differential detection scheme for compact CPT atomic clocks[J]. Europhysics Letters, 119, 23001(2017).

    [47] DUAN L H, QUAN W, JIANG L W, et al. Common-mode noise reduction in an atomic spin gyroscope using optical differential detection[J]. Applied Optics, 56, 7734-7740(2017).

    [48] LU B, MORGAN S P, CROWE J A, et al. Comparison of methods for reducing the effects of scattering in spectrophotometry[J]. Applied Spectroscopy, 60, 1157-1166(2006).

    Huihui ZHAI, Xiangyu KANG, Yan CAO, Yang LI, Xiangmei DONG, Xiumin GAO. Research progress on detection methods of weak magnetic signal in all-optical atomic magnetometer[J]. Optical Instruments, 2024, 46(1): 70
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