发表论文
[18]. Y. Luo*, Y. Chu*, X. Fu, J. Canning, J. Wang, J. Zhang, B. Yan, J. Wen, T. Wang, G. D. Peng. 3D printing specialty multi-function twin core Bi/Er co-doped silica optical fibres for ultra-broadband polarized near infrared emission and sensing applications. Optics & Laser Technology, 168(21): 109817, 2024. (*corresponding authors)
[17]. K. Zhang, J. Bai, X. Wan, L. Dong, S. Wang, H. Pan, Y. Chu*, J. Ren, J. Zhang*, G. D. Peng. Facile Fabrication of Silica Glass Embedded with NiO Nanoparticles by 3D Printing Technology and its Optical Nonlinearity. Advanced Photonics Research, 5, 2300244, 2024. (*corresponding authors)
[16]. L. Dong, J. Bai, X. Wan, Z. Wu, H. Zhao, Y. Li, T. Guo, K. Zhang, J. Wang, Y. Chu*, J. Zhang*, G. D. Peng. Effect of sintering condition on the attenuation of silica glasses fabricated by additive manufacturing, Ceramics International, 49(23), 39400-39408, 2023. (*corresponding authors)
[15]. 楚玉石,张建中,彭纲定,增材制造在特种石英光纤制备中应用的研究进展,激光与光电子学进展,59: (15), 1516003, 2022.(2022联合国国际玻璃年特刊,特邀综述,期刊封面)
[14]. Y. Chu, X. Fu, Y, Luo, et al. Additive Manufacturing Fiber Preforms for Structured Silica Fibers with Bismuth and Erbium Dopants, Light: Advanced Manufacturing, 3: (21), 1-7, 2022.
[13]. Y. Chu, X. Fu, Y. Luo, et al. 3D Printed Silica Optical Fibre-a “Game Changer” Technology in Optical Fibre Manufacture, Specialty Optical Fibers, SoM3H. 6, 2020.
[12]. Y. Tian, Y. Chu, Y. Luo, et al. Birefringence Measurement by Expandable Polarization Interference Method, Journal of Lightwave Technology, 38: (4), 834-839, 2020.
[11]. Y. Chu, X. Fu, Y. Luo, et al. Silica optical fiber drawn from 3D printed preforms, Optics Letters, 44: (21), 5358-5361, 2019. (Editor's Pick, Journal News, Science Daily, Design News, The Engineer et al news)
[10]. Y. Chu, Y. Tian, D. Fan, et al. Fabrication and Characterization of Birefringent Bismuth and Erbium Co-Doped Photonic Crystal Fiber for Broadband Polarized Near Infrared Emission, Conference on Lasers and Electro-Optics, JW2A.107, 2019.
[9] J. Hao*, Y. Chu*, Z. Ma, et al. Effects of thermal treatment on photoluminescence properties of bismuth/erbium co-doped optical fibers, Optical Fiber Technology, 46, 141-146, 2018. (*Contributed Equally)
[8] Y. Luo, Y. Chu, K. Cook, et al. Spun high birefringence bismuth/erbium co-doped photonic crystal fibre with broadband polarized emission, Asia Communications and Photonics Conference, 2018.
[7] X. Wang, Y. Chu, Z. Yang, et al. Broadband multicolor upconversion from Yb3+–Mn2+ codoped fluorosilicate glasses and transparent glass ceramics, Optics Letters, 43: (20), 5013-5016, 2018.
[6]. Y. Chu, Q. Hu, Y. Zhang, et al. Topological Engineering of Photoluminescence Properties of Bismuth‐ or Erbium‐Doped Phosphosilicate Glass of Arbitrary P2O5 to SiO2 Ratio, Advanced Optical Materials, 6: (13), 1800024, 2018. (Journal Cover)
[5]. Z. Gao, X. Lu, Y. Chu, et al. The distribution of rare earth ions in a γ-Ga2O3 nanocrystal-silicate glass composite and its influence on the photoluminescence properties, Journal of Materials Chemistry C, 6: (12), 2944-2950, 2018. (Journal Cover)
[4]. J. Ren, Y. Chu, Q. Hu, et al. Spectroscopic properties of Ce3+/Yb3+/Ho3+ triply doped bismuthate glasses, Journal of Alloys and Compounds, 717, 171-176, 2017.
[3]. Y. Chu, J. Hao, J. Zhang, et al. Temperature properties and potential temperature sensor based on the Bismuth/Erbium co-doped optical fibers, 25th Optical Fiber Sensors Conference, 103237I, 2017.
[2]. Y. Chu, J. Ren, J. Zhang, et al. Ce 3+/Yb3+/Er3+ triply doped bismuth borosilicate glass: a potential fiber material for broadband near-infrared fiber amplifiers, Scientific Reports, 6: (1), 1-9, 2016.
[1]. Y. Chu, J. Ren, J. Zhang, et al. Effects of melting temperature and composition on spectroscopic properties of Er3+-doped bismuth glasses, Optical Materials Express, 6: (1), 279-287, 2016.
