[1] Kasevich M, Chu S. Atomic interferometry using stimulated Raman transitions[J]. Physical Review Letters, 67, 181-184(1991).
[2] Hauth M, Freier C, Schkolnik V et al. First gravity measurements using the mobile atom interferometer GAIN[J]. Applied Physics B, 113, 49-55(2013).
[3] Hu Z K, Sun B L, Duan X C et al. Demonstration of an ultrahigh-sensitivity atom-interferometry absolute gravimeter[J]. Physical Review A, 88, 043610(2013).
[4] Zhou L, Xiong Z Y, Yang W et al. Measurement of local gravity via a cold atom interferometer[J]. Chinese Physics Letters, 28, 013701(2011).
[5] Freier C, Hauth M, Schkolnik V et al. Mobile quantum gravity sensor with unprecedented stability[J]. Journal of Physics: Conference Series, 723, 012050(2016).
[6] Fang B, Dutta I, Gillot P et al. Metrology with atom interferometry: Inertial sensors from laboratory to field applications[J]. Journal of Physics: Conference Series, 723, 012049(2016).
[7] Rosi G, Cacciapuoti L, Sorrentino F et al. Measurement of the gravity-field curvature by atom interferometry[J]. Physical Review Letters, 114, 013001(2015).
[8] Dickerson S M, Hogan J M, Sugarbaker A et al. Multiaxis inertial sensing with long-time point source atom interferometry[J]. Physical Review Letters, 111, 083001(2013).
[9] McGuinness H J, Rakholia A V, Biedermann G W. High data-rate atom interferometer for measuring acceleration[J]. Applied Physics Letters, 100, 011106(2012).
[10] Niebauer T M, Sasagawa G S, Faller J E et al. A new generation of absolute gravimeters[J]. Metrologia, 32, 159-180(1995).
[11] Timmen L, Gitlein O, Klemann V et al. Observing gravity change in the Fennoscandian uplift area with the Hanover absolute gravimeter[J]. Pure and Applied Geophysics, 169, 1331-1342(2012).
[12] Bidel Y, Zahzam N, Blanchard C et al. Absolute marine gravimetry with matter-wave interferometry[J]. Nature Communications, 9, 627(2018).
[13] Bidel Y, Carraz O, Charrière R et al. Compact cold atom gravimeter for field applications[J]. Applied Physics Letters, 102, 144107(2013).
[14] Schmidt M, Senger A, Hauth M et al. A mobile high-precision absolute gravimeter based on atom interferometry[J]. Gyroscopy and Navigation, 2, 170-177(2011).
[15] Wang S K, Zhao Y, Zhuang W et al. Shift evaluation of the atomic gravimeter NIM-AGRb-1 and its comparison with FG5X[J]. Metrologia, 55, 360-365(2018).
[16] Wu B, Wang Z Y, Cheng B et al. The investigation of a μGal-level cold atom gravimeter for field applications[J]. Metrologia, 51, 452-458(2014).
[17] Chen B, Long J B, Xie H T et al. Portable atomic gravimeter operating in noisy urban environments[J]. Chinese Optics Letters, 18, 090201(2020).
[18] Huang P W, Tang B, Chen X et al. Accuracy and stability evaluation of the 85Rb atom gravimeter WAG-H5-1 at the 2017 international comparison of absolute gravimeters[J]. Metrologia, 56, 045012(2019).
[19] Cao L, Lu S B, Wang K et al. Investigation of preparation and phase noise of Raman laser based on optical phase-locked loop[J]. Chinese Journal of Quantum Electronics, 35, 402-407(2018).
[20] Thorpe J I, Numata K, Livas J. Laser frequency stabilization and control through offset sideband locking to optical cavities[J]. Optics Express, 16, 15980-15990(2008).
[21] Theron F, Carraz O, Renon G et al. Narrow linewidth single laser source system for onboard atom interferometry[J]. Applied Physics B, 118, 1-5(2015).
[22] Battelier B, Barrett B, Fouché L et al. Development of compact cold-atom sensors for inertial navigation[C](2016).
[23] Wu X J, Zi F, Dudley J et al. Multiaxis atom interferometry with a single-diode laser and a pyramidal magneto-optical trap[J]. Optica, 4, 1545-1551(2017).
[24] Oon F E, Dumke R. Compact single-seed, module-based laser system on a transportable high-precision atomic gravimeter[J]. AVS Quantum Science, 4, 044401(2022).
[25] Fang J, Hu J G, Chen X et al. Realization of a compact one-seed laser system for atom interferometer-based gravimeters[J]. Optics Express, 26, 1586-1596(2018).
[26] Huang D X, Liu X F[M]. Semiconductor Lasers and Their Applications(1999).
