Ultra-low noise 2 μm high power single-frequency fiber laser for next generation gravitational-wave detector (Invited)

Yubin Hou; Xiangwen Lu; Qian Zhang; Pu Wang

doi:10.3788/IRLA20220400

[1] Lippert E, Rustad G, Nicolas S, et al. Fibrelaserpumped infrared source[C]Proceedings of SPIE, 2004, 5620: 5662.

[2] Chuang T, Litvinovitch S, Engin D, et al. Compact, highly efficient, singlefrequency 25 W, 2051 nm Tm fiberbased MOPA f CO2 tracegas laser space transmitter[C]Lidar Remote Sensing f Environmental Moniting, 2017.

[3] S W Henderson, C P Hale, J R Magee, et al. Eye-safe coherent laser radar system at 2.1 μm using Tm, Ho: YAG lasers. Optics Letters, 16, 773-775(1991).

[4] Z Li, A M Heidt, J M O Daniel, et al. Thulium-doped fiber amplifier for optical communications at 2 m. Optics Express, 21, 9289-9297(2013).

[5] Geng J, Wang Q, Jiang S. 2μm fiber laser sources their applications[C]Proceedings of SPIE, 2011, 8164(1): 314.

[6] B Shapiro, R X Adhikari, O Aguiar, et al. Cryogenically cooled ultra-low vibration silicon mirrors for gravitational wave observatories. Cryogenics, 81, 83-92(2017).

[7] Karlmann P B, Klein K J, Halverson P G, et al. Linear thermal expansion measurements of single crystal silicon f validation of interferometer based cryogenic dilatometer[C]AIP Conference, 2006.

[8] J C Driggers, J Harms, R X Adhikari. Subtraction of Newtonian noise using optimized sensor arrays. Physical Review D, 86, 102001(2012).

[9] W N Zhang, C Li, S P Mo, et al. A compact low noise single frequency linearly polarized dbr fiber laser at 1550 nm. Chinese Physics Letters, 29, 1028-1032(2012).

[10] Voo N Y. Development, acterisation analysis of narrow linewidth, singlefrequency DFB fibre lasers in the 1.5 μm2 μm region[D]. Southampton, Hampshire, UK: University of Southampton, 2006.

[11] K Iwatsuki, H Okamura, M Saruwatari. Wavelength-tunable single-frequency and single-polarisation Er-doped fibre ring-laser with 1.4 kHz linewidth. Electronics Letters, 26, 2033-2035(1990).

[12] J Geng, J Wu, S Jiang, et al. Efficient operation of diode-pumped single-frequency thulium-doped fiber lasers near 2 μm. Opt Lett, 32, 355-357(2007).

[13] Q Yang, S H Xu, C Li, et al. A single-frequency linearly polarized fiber laser using a newly developed heavily Tm³⁺-doped germanate glass fiber at 1.95μm. Chinese Physics Letters, 32, 62-65(2015).

[14] S Fu, W Shi, Q Sheng, et al. Compact hundred-mW 2 μm single-frequency thulium-doped silica fiber laser. IEEE Photonics Technology Letters, 29, 853-856(2017).

[15] X Guan, C Yang, T Qiao, et al. High-efficiency sub-watt in-band-pumped single-frequency DBR Tm³⁺-doped germanate fiber laser at 1950 nm. Optics Express, 26, 6817-6825(2018).

[16] S B Foster, A E Tikhomirov. Pump-Noise contribution to frequency noise and linewidth of distributed-feedback fiber lasers. IEEE Journal of Quantum Electronics, 46, 734-741(2010).

[17] S Setzler, M P Francis, Y E Young, et al. Resonantly pumped eyesafe erbium lasers. IEEE Journal of Selected Topics in Quantum Electronics, 11, 645-657(2005).

[18] D Xu, F Yang, D Chen, et al. Laser phase and frequency noise measurement by Michelson interferometer composed of a 3 × 3 optical fiber coupler. Optics Express, 23, 22386-22393(2015).