Researching | Design and Laser Dynamics of Zerodur‑Based Full‑Inner‑Cavity Large Laser Gyroscopes

Journals >Chinese Journal of Lasers >Volume 51 >Issue 22 >Page 2201004 > Article

Chinese Journal of Lasers
Vol. 51, Issue 22, 2201004 (2024)

Design and Laser Dynamics of Zerodur‑Based Full‑Inner‑Cavity Large Laser Gyroscopes

Yuanhao Mao^1,2, Zhongqi Tan^1,2,*, Dingbo Chen^1,2, Qiucheng Gong^1,2..., Bin Zhang^1,2, Suyong Wu^1,2, Jianping Liu^1,2, Zhenfang Fan^1,2, Hui Luo^1,2 and Xingwu Long^1,2|Show fewer author(s)

Author Affiliations

¹College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, Hunan , China

²Nanhu Laser Laboratory, National University of Defense Technology, Changsha 410073, Hunan , China

show less

DOI: 10.3788/CJL240511 Cite this Article Set citation alerts

Yuanhao Mao, Zhongqi Tan, Dingbo Chen, Qiucheng Gong, Bin Zhang, Suyong Wu, Jianping Liu, Zhenfang Fan, Hui Luo, Xingwu Long. Design and Laser Dynamics of Zerodur‑Based Full‑Inner‑Cavity Large Laser Gyroscopes[J]. Chinese Journal of Lasers, 2024, 51(22): 2201004 Copy Citation Text

show less

References

[1] Li J R, Li H Y, Jiang Z C. The analyze of the launch window for space rescue mission[J]. Journal of National University of Defense Technology, 30, 10-14(2008).

[2] Wang W, Feng W S, Zhang S G et al. Research on technology of large-scale high-precision fiber optic gyroscope for universal time measurement[J]. Navigation and Control, 20, 1-8(2021).

[3] Liu M, Sun Y, Gu Z B et al. Re-discussed about leap second in coordinate universal time in 2020[J]. Journal of Time and Frequency, 44, 153-162(2021).

[4] Wu Y W, Li X S, Sun B Q et al. The NTSC’s universal time measurement and service system[J]. Journal of Time and Frequency, 45, 184-193(2022).

[5] Nilsson T, Böhm J, Schuh H et al. Combining VLBI and ring laser observations for determination of high frequency Earth rotation variation[J]. Journal of Geodynamics, 62, 69-73(2012).

[6] Zhang Y H. Research on earth rotation parameters of GNSS/VLBI/SLR multi-source data fusion epoch reference frame[D](2019).

[7] Anderson R, Bilger H R, Stedman G E. “Sagnac” effect: A century of Earth-rotated interferometers[J]. American Journal of Physics, 62, 975-985(1994).

[8] Stedman G E. Ring-laser tests of fundamental physics and geophysics[J]. Reports on Progress in Physics, 60, 615-688(1997).

[9] Schreiber U K, Rowe C H, Wright D N et al. Precision stabilization of the optical frequency in a large ring laser gyroscope[J]. Applied Optics, 37, 8371-8381(1998).

[10] Rowe C H, Schreiber U K, Cooper S J et al. Design and operation of a very large ring laser gyroscope[J]. Applied Optics, 38, 2516(1999).

[11] Schreiber K U, Gebauer A, Igel H et al. The centennial of the Sagnac experiment in the optical regime: From a tabletop experiment to the variation of the Earth’s rotation[J]. Comptes Rendus Physique, 15, 859-865(2014).

[12] Schreiber K U, Wells J P R. Invited review article: Large ring lasers for rotation sensing[J]. The Review of Scientific Instruments, 84, 041101(2013).

[13] Schreiber K U, Klügel T, Velikoseltsev A et al. The large ring laser G for continuous earth rotation monitoring[J]. Pure and Applied Geophysics, 166, 1485-1498(2009).

[14] Schreiber K U, Klügel T, Wells J P R et al. How to detect the chandler and the annual wobble of the earth with a large ring laser gyroscope[J]. Physical Review Letters, 107, 173904(2011).

[15] Schreiber K U, Gebauer A, Wells J P R. Long-term frequency stabilization of a 16 m2 ring laser gyroscope[J]. Optics Letters, 37, 1925-1927(2012).

[16] Schreiber K U, Gebauer A, Wells J P R. Closed-loop locking of an optical frequency comb to a large ring laser[J]. Optics Letters, 38, 3574-3577(2013).

[17] Schreiber K U, Kodet J, Hugentobler U et al. Variations in the Earth’s rotation rate measured with a ring laser interferometer[J]. Nature Photonics, 17, 1054-1058(2023).

[18] Zheng X, Li Y J. Loss variation of space triaxial laser gyro mirrors exposed to discharge plasma[J]. Chinese Journal of Lasers, 50, 2301005(2023).

[19] Xi L, Yin C, Wang J B et al. Research on thermal-frequency characteristics of 633 nm internal-mirror He-Ne laser[J]. Chinese Journal of Lasers, 49, 0601002(2022).

[20] Endo M, Walter R F[M]. Gas lasers(2018).

[21] An K[M]. Fundamentals of laser physics(2023).

[22] Coffey D, Lorents D C, Smith F T. Collision spectroscopy. II. inelastic scattering of He+ by Ne[J]. Physical Review A, 2, 549(1970).

[23] Olson R E, Smith F T. Collision spectroscopy. IV. semiclassical theory of inelastic scattering with application to He++ Ne[J]. Physical Review A, 6, 526(1972).

[24] Nayfeh M H, Chen C H, Payne M G. Kinetic study of energy transfer from He (n=2, 3) to Ne, Ar, Kr, and Xe[J]. Physical Review A, 14, 1739-1744(1976).

[25] Krenos J. Electronic energy transfer in He*(21S)+Ne collisions: Propensity for odd-J levels of Ne*(5s, 5s′, 4d)[J]. Physical Review A, 29, 1844-1849(1984).

[26] Manders M P I, Driessen J P J, Beijerinck H C W et al. Collision-induced intramultiplet mixing for Ne**(2p)5(3p) +He: Experiments and quantum calculations[J]. Physical Review A, 37, 3237-3253(1988).

[27] Bahrim C, Kucal H, Masnou-Seeuws F. Absolute cross sections with polarization effects in Ne*(2p53p)+He collisions: A detailed comparison between theory and experiment[J]. Physical Review A, 56, 1305-1320(1997).

[28] Ariyasinghe W M, Goains C, Powers D et al. Total electron scattering cross sections of He, Ne and Ar at intermediate electron energies[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 225, 191-197(2004).

[29] Hurst R B, Dunn R W, Schreiber K U et al. Mode behavior in ultralarge ring lasers[J]. Applied Optics, 43, 2337-2346(2004).

[30] Holdaway J, Hurst R B, Graham R et al. Self-locked operation of large He-Ne ring laser gyroscopes[J]. Metrologia, 49, 209-212(2012).

[31] Jiang Y N[M]. Ring laser gyro(1985).

[32] Belfi J, Beverini N, Bosi F et al. Deep underground rotation measurements: GINGERino ring laser gyroscope in Gran Sasso[J]. The Review of Scientific Instruments, 88, 034502(2017).

[33] Gebauer A, Tercjak M, Schreiber K U et al. Reconstruction of the instantaneous earth rotation vector with sub-arcsecond resolution using a large scale ring laser array[J]. Physical Review Letters, 125, 033605(2020).

[34] Igel H, Schreiber K U, Gebauer A et al. ROMY: A multicomponent ring laser for geodesy and geophysics[J]. Geophysical Journal International, 225, 684-698(2021).

[35] Chow W W, Gea-Banacloche J, Pedrotti L M et al. The ring laser gyro[J]. Reviews of Modern Physics, 57, 61-104(1985).

[36] Schreiber U, Schneider M, HRoweet al C. The C-II ring laser project[J]. Physics and Chemistry of the Earth, 25, 805-807(2000).

[37] Yan C Z, Shi H S, Yao Y et al. Automatic, long-term frequency-stabilized lasers with sub-hertz linewidth and 10-16 frequency instability[J]. Chinese Optics Letters, 20, 070201(2022).

[38] Yu Q Y, Wang J B, Yin C et al. Research on precise wavelength measurement of 543 nm frequency stabilized He-Ne laser using optical frequency comb[J]. Chinese Journal of Lasers, 51, 1304003(2024).

Get PDF(in Chinese)

Figures&Tables (5)

References (38)

Copy Citation Text

Yuanhao Mao, Zhongqi Tan, Dingbo Chen, Qiucheng Gong, Bin Zhang, Suyong Wu, Jianping Liu, Zhenfang Fan, Hui Luo, Xingwu Long. Design and Laser Dynamics of Zerodur‑Based Full‑Inner‑Cavity Large Laser Gyroscopes[J]. Chinese Journal of Lasers, 2024, 51(22): 2201004

Download Citation

Set citation alerts for the article

Set citation alerts for the article

Save the article for my favorites

Paper Information

Recommended Topics

laser devices and laser physics

Lasers and Laser Optics

laser manufacturing

Instrumentation, Measurement and Metrology

Set citation alerts for the article

Please enter your email address