Researching | Polarization and magneto-optical characteristics of Tb:YAG crystal-derived silica fiber via laser-heating drawing technique

Journals >Chinese Optics Letters >Volume 21 >Issue 11 >Page 110601 > Article

Chinese Optics Letters
Vol. 21, Issue 11, 110601 (2023)

Polarization and magneto-optical characteristics of Tb:YAG crystal-derived silica fiber via laser-heating drawing technique

Hao Shi, Jianxiang Wen^*, Beibei Xing, Yanhua Luo, Xiaobei Zhang, Fufei Pang, and Tingyun Wang

Author Affiliations

Key Laboratory of Specialty Fiber Optics and Optical Access Networks, Joint International Research Laboratory of Specialty Fiber Optics and Advanced Communication, School of Communication and Information Engineering, Shanghai University, Shanghai 200444, China

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DOI: 10.3788/COL202321.110601 Cite this Article Set citation alerts

Hao Shi, Jianxiang Wen, Beibei Xing, Yanhua Luo, Xiaobei Zhang, Fufei Pang, Tingyun Wang, "Polarization and magneto-optical characteristics of Tb:YAG crystal-derived silica fiber via laser-heating drawing technique," Chin. Opt. Lett. 21, 110601 (2023) Copy Citation Text

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References

[1] V. Temkina, A. Medvedev, A. Mayzel. Research on the methods and algorithms improving the measurements precision and market competitive advantages of fiber optic current sensors. Sensors, 20, 5995(2020).

[2] K. Bohnert, C.-P. Hsu, L. Yang, A. Frank, G. M. Müller, P. Gabus. Fiber-optic current sensor tolerant to imperfections of polarization-maintaining fiber connectors. J. Light. Technol., 36, 2161(2018).

[3] R. M. Silva, H. Martins, I. Nascimento, J. M. Baptista, A. L. Ribeiro, J. L. Santos, P. Jorge, O. Frazão. Optical current sensors for high power systems: a review. Appl. Sci., 2, 602(2012).

[4] H. Gao, G. Wang, W. Gao, S. Li, Y. Wang, B. Zhao, R. Zhang. A method for suppressing error of fiber optic current transformer caused by temperature based on λ/4 wave plate fabricated with polarization maintaining photonic crystal fiber. IEEE Sens. J., 23, 10517(2023).

[5] Z. Shi, M. Ji, J. Lin, M. Li, Y. Bai. Quarter wave plate made by cutting straight holey birefringent fiber. Proc. SPIE, 7134, 713449(2008).

[6] A. H. Rose, N. Feat, S. M. Etzel. Wavelength and temperature performance of polarization-transforming fiber. Appl. Opt., 42, 6897(2003).

[7] N. Peng, Y. Huang, S. Wang, T. Wen, W. Liu, Q. Zuo, L. Wang. Fiber optic current sensor based on special spun highly birefringent fiber. IEEE Photon. Technol. Lett., 25, 1668(2013).

[8] P. Yao, X. Chen, P. Hao, H. Xiao, Z. Ding, T. Liu, X. S. Yao. Introduction and measurement of the effective Verdet constant of spun optical fibers. Opt. Express, 29, 23315(2021).

[9] D. F. Franco, R. G. Fernandes, J. F. Felix, V. R. Mastelaro, H. Eckert, C. R. M. Afonso, Y. Messaddeq, S. H. Messaddeq, S. Morency, M. Nalin. Fundamental studies of magneto-optical borogermanate glasses and derived optical fibers containing Tb3+. J. Mater. Res. Technol., 11, 312(2021).

[10] K. Linganna, S. Ju, Y. Lee, W.-T. Han. Development of aluminosilicate glass fiber doped with high Pr3+ concentration for all-optical fiber isolator application. J. Mater. Sci. Mater. Electron., 30, 12790(2019).

[11] Q. Chen, H. Wang, Q. Wang, Q. Chen. Faraday rotation influence factors in tellurite-based glass and fibers. Appl. Phys. A, 120, 1001(2015).

[12] L. Sun, S. Jiang, J. D. Zuegel, J. R. Marciante. All-fiber optical isolator based on Faraday rotation in highly terbium-doped fiber. Opt. Lett., 35, 706(2010).

[13] Y. Huang, H. Chen, W. Dong, F. Pang, J. Wen, Z. Chen, T. Wang. Fabrication of europium-doped silica optical fiber with high Verdet constant. Opt. Express, 24, 18709(2016).

[14] L. Yang, J. X. Wen, Y. Wu, Y. Wan, L. Z. Zeng, W. Chen, F. F. Pang, X. B. Zhang, T. Y. Wang. High signal-to-noise ratio fiber laser at 1596 nm based on a Bi/Er/La co-doped silica fiber. Chin. Opt. Lett., 20, 051402(2022).

[15] Y. G. Chen, Z. Q. Lin, Y. F. Wang, M. Wang, L. Zhang, Y. Jiao, H. H. Dong, S. K. Wang, C. L. Yu, L. L. Hu. Nd3+-doped silica glass and fiber prepared by modified sol-gel method. Chin. Opt. Lett., 20, 091601(2022).

[16] Q. Guo, J. Wen, Y. Huang, W. Wang, F. Pang, Z. Chen, Y. Luo, G.-D. Peng, T. Wang. Magneto-optical properties and measurement of the novel doping silica optical fibers. Measurement, 127, 63(2018).

[17] J. Wen, Q. Che, Y. Dong, Q. Guo, F. Pang, Z. Chen, T. Wang. Irradiation effect on the magneto-optical properties of Bi-doped silica optical fiber based on valence state change. Opt. Mater. Express, 10, 88(2020).

[18] S. Zheng, J. Li, C. Yu, Q. Zhou, D. Chen. Preparation and characterizations of Nd:YAG ceramic derived silica fibers drawn by post-feeding molten core approach. Opt. Express, 24, 24248(2016).

[19] G. Tang, G. Qian, W. Lin, W. Wang, Z. Shi, Y. Yang, N. Dai, Q. Qian, Z. Yang. Broadband 2 µm amplified spontaneous emission of Ho/Cr/Tm: YAG crystal derived all-glass fibers for mode-locked fiber laser applications. Opt. Lett., 44, 3290(2019).

[20] Y. Wan, J. Wen, C. Jiang, F. Tang, J. Wen, S. Huang, F. Pang, T. Wang. Over 255 mW single-frequency fiber laser with high slope efficiency and power stability based on an ultrashort Yb-doped crystal-derived silica fiber. Photonics Res., 9, 649(2021).

[21] J. Ballato, A. C. Peacock. Perspective: molten core optical fiber fabrication—a route to new materials and applications. APL Photonics, 3, 120903(2018).

[22] X. Ji, S. Lei, S.-Y. Yu, H. Y. Cheng, W. Liu, N. Poilvert, Y. Xiong, I. Dabo, S. E. Mohney, J. V. Badding, V. Gopalan. Single-crystal silicon optical fiber by direct laser crystallization. ACS Photonics, 4, 85(2017).

[23] H. Yang, Z. Zhu. Magneto-optical glass mixed with Tb3+ ions: high Verdet constant and luminescence properties. J. Lumin., 231, 117804(2021).

[24] D. H. Goldstein, L. L. Deibler, B. B. Wang. Measurement of small birefringence in sapphire and quartz plates. Proc. SPIE, 4819, 20(2002).

[25] E. Kuzin, J. M. Estudillo-Ayala, B. Ibarra-Escamilla, J. Haus. Measurements of beat length in short low-birefringence fibers. Opt. Lett., 26, 1134(2001).

[26] Y. Yang, W. Duan, M. Ye. High precision measurement technology for beat length of birefringence optical fiber. Meas. Sci. Technol., 24, 025201(2013).

[27] V. F. Nezhad, C. L. You, G. Veronis. Nanoplasmonic magneto-optical isolator. Chin. Opt. Lett., 19, 083602(2021).

[28] M. Basharat, M. Ding, Y. Li, H. W. Cai, J. C. Fang. Noise reduction and signal to noise ratio improvement in magneto-optical polarization rotation measurement. Chin. Opt. Lett., 16, 081201(2018).

[29] T. Chartier, A. Hideur, C. Özkul, F. Sanchez, G. M. Stéphan. Measurement of the elliptical birefringence of single-mode optical fibers. Appl. Opt., 40, 5343(2001).

[30] J. Cruz, M. V. Andres, M. Hernandez. Faraday effect in standard optical fibers: dispersion of the effective Verdet constant. Appl. Opt., 35, 922(1996).

[31] K. Zou, J. Wen, Y. Wan, Y. Wu, F. Pang, T. Wang. Heat-induced emission enhancement in a Yb:YAG crystal-derived silica fiber. Photonics, 9, 706(2022).

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Hao Shi, Jianxiang Wen, Beibei Xing, Yanhua Luo, Xiaobei Zhang, Fufei Pang, Tingyun Wang, "Polarization and magneto-optical characteristics of Tb:YAG crystal-derived silica fiber via laser-heating drawing technique," Chin. Opt. Lett. 21, 110601 (2023)

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