[1] A. D. Ludlow, M. M. Boyd, J. Ye, E. Peik, P. O. Schmidt. Optical atomic clocks. Rev. Mod. Phys., 87, 637(2015).
[2] I. Ushijima, M. Takamoto, M. Das, T. Ohkubo, H. Katori. Cryogenic optical lattice clocks. Nat. Photonics, 9, 185(2015).
[3] N. Huntemann, C. Sanner, B. Lipphardt, C. Tamm, E. Peik. Single-ion atomic clock with 3 × 10-18 systematic uncertainty. Phys. Rev. Lett., 116, 063001(2016).
[4] R. X. Adhikari. Gravitational radiation detection with laser interferometry. Rev. Mod. Phys., 86, 121(2014).
[5] Y. Duan, Y. Huang, Y. Li, Y. Wang, M. Ye, M. Li, Y. Chen, J. Zhou, L. Wang, L. Liu, T. Li. All-fiber-based photonic microwave generation with 10−15 frequency instability. Chin. Opt. Lett., 20, 021406(2022).
[6] S. Herrmann, A. Senger, K. Möhle, M. Nagel, E. V. Kovalchuk, A. Peters. Rotating optical cavity experiment testing Lorentz invariance at the 10-17 level. Phys. Rev. D, 80, 105011(2009).
[7] D. G. Matei, T. Legero, S. Häfner, C. Grebing, R. Weyrich, W. Zhang, L. Sonderhouse, J. M. Robinson, J. Ye, F. Riehle, U. Sterr. 1.5 µm lasers with sub-10 mHz linewidth. Phys. Rev. Lett., 118, 263202(2017).
[8] W. Zhang, J. M. Robinson, L. Sonderhouse, E. Oelker, C. Benko, J. L. Hall, T. Legero, D. G. Matei, F. Riehle, U. Sterr, J. Ye. Ultrastable silicon cavity in a continuously operating closed-cycle cryostat at 4 K. Phys. Rev. Lett., 119, 243601(2017).
[9] L. Jin, Y. Jiang, Y. Yao, H. Yu, Z. Bi, L. Ma. Laser frequency instability of 2 × 10-16 by stabilizing to 30-cm-long Fabry-Pérot cavities at 578 nm. Opt. Express, 26, 18699(2018).
[10] J. Grotti, S. Koller, S. Vogt, S. Häfner, U. Sterr, C. Lisdat, H. Denker, C. Voigt, L. Timmen, A. Rolland, F. N. Baynes, H. S. Margolis, M. Zampaolo, P. Thoumany, M. Pizzocaro, B. Rauf, F. Bregolin, A. Tampellini, P. Barbieri, M. Zucco, G. A. Costanzo, C. Clivati, F. Levi, D. Calonico. Geodesy and metrology with a transportable optical clock. Nat. Phys., 14, 437(2018).
[11] G. Wang, Z. Li, J. Huang, H. Duan, X. Huang, H. Liu, Q. Liu, S. Yang, L. Tu, H. Yeh. Analysis and suppression of thermal effect of an ultra-stable laser interferometer for space-based gravitational waves detection. Chin. Opt. Lett., 20, 011203(2022).
[12] J. Luo, L.-S. Chen, H.-Z. Duan, Y.-G. Gong, S. Hu, J. Ji, Q. Liu, J. Mei, V. Milyukov, M. Sazhin, C.-G. Shao, V. T. Toth, H.-B. Tu, Y. Wang, Y. Wang, H.-C. Yeh, M.-S. Zhan, Y. Zhang, V. Zharov, Z.-B. Zhou. TianQin: a space-borne gravitational wave detector. Class. Quantum Grav., 33, 035010(2016).
[13] O. Lopez, A. Haboucha, F. Kéfélian, H. Jiang, B. Chanteau, V. Roncin, C. Chardonnet, A. Amy-Klein, G. Santarelli. Cascaded multiplexed optical link on a telecommunication network for frequency dissemination. Opt. Express, 18, 16849(2010).
[14] F. Kéfélian, H. Jiang, P. Lemonde, G. Santarelli. Ultralow-frequency-noise stabilization of a laser by locking to an optical fiber-delay line. Opt. Lett., 34, 914(2009).
[15] H. Jiang, F. Kéfélian, P. Lemonde, A. Clairon, G. Santarelli. An agile laser with ultra-low frequency noise and high sweep linearity. Opt. Express, 18, 3284(2010).
[16] J. Dong, Y. Hu, J. Huang, M. Ye, Q. Qu, T. Li, L. Liu. Subhertz linewidth laser by locking to a fiber delay line. Appl. Opt., 54, 1152(2015).
[17] J. Huang, L. Wang, Y. Duan, Y. Huang, M. Ye, L. Liu, T. Li. All-fiber-based laser with 200 mHz linewidth. Chin. Opt. Lett., 17, 071407(2019).
[18] J. Hough, S. Rowan. Laser interferometry for the detection of gravitational waves. J. Opt. A, 7, S257(2005).
[19] V. Lavielle, I. Lorgeré, J.-L. Le Gouët, S. Tonda, D. Dolfi. Wideband versatile radio-frequency spectrum analyzer. Opt. Lett., 28, 384(2003).
[20] M. Harris, G. N. Pearson, J. M. Vaughan, D. Letalick, C. Karlsson. The role of laser coherence length in continuous-wave coherent laser radar. J. Mod. Opt., 45, 1567(1998).
[21] N. Yang, Q. Qiu, J. Su, S. Shi. Research on the temperature characteristics of optical fiber refractive index. Optik, 125, 5813(2014).
[22] J. Leng, A. Asundi. Structural health monitoring of smart composite materials by using EFPI and FBG sensors. Sens. Actuator. A Phys., 103, 330(2003).
[23] K. E. Hrdina, C. A. Duran. ULE ® glass with improved thermal properties for EUVL masks and projection optics substrates. Int. J. Appl. Glass Sci., 5, 82(2014).
[24] J. Huang, L. Wang, Y. Duan, Y. Huang, M. Ye, L. Li, L. Liu, T. Li. Vibration-insensitive fiber spool for laser stabilization. Chin. Opt. Lett., 17, 081403(2019).
[25] W. Zhu, E. R. Numkam Fokoua, A. A. Taranta, Y. Chen, T. Bradley, M. N. Petrovich, F. Poletti, M. Zhao, D. J. Richardson, R. Slavik. The thermal phase sensitivity of both coated and uncoated standard and hollow core fibers down to cryogenic temperatures. J. Light. Technol., 38, 2477(2020).
[26] E. N. Fokoua, M. N. Petrovich, T. Bradley, F. Poletti, D. J. Richardson, R. Slavík. How to make the propagation time through an optical fiber fully insensitive to temperature variations. Optica, 4, 659(2017).
[27] T. Yoshino, T. Hashimoto, M. Nara, K. Kurosawa. Common path heterodyne optical fiber sensors. J. Light. Technol., 10, 503(1992).