[1] [1] HE D B, YU C L, CHENG J M, et al. Effect of Tb3+ concentration and sensitization of Ce3+ on luminescence properties of terbium doped phosphate scintillating glass［J］. Journal of Alloys and Compounds, 2011, 509(5): 1906-1909.

[2] [2] HAYAKAWA T, KAMATA N, YAMADA K. Visible emission characteristics in Tb3+-doped fluorescent glasses under selective excitation［J］. Journal of Luminescence, 1996, 68(2/3/4): 179-186.

[3] [3] THULASIRAMUDU A, BUDDHUDU S. Optical characterization of Eu3+ and Tb3+ ions doped zinc lead borate glasses［J］. Spectrochimica Acta Part A, Molecular and Biomolecular Spectroscopy, 2007, 66(2): 323-328.

[4] [4] YAMASHITA T, OHISHI Y. Cooperative energy transfer between Tb3+ and Yb3+ ions co-doped in borosilicate glass［J］. Journal of Non-Crystalline Solids, 2008, 354(17): 1883-1890.

[5] [5] QIAO Y P. Luminescence, energy transfer and tunable white emitting of borosilicate glass doubly doped with Tb/Sm or triply doped with Ce/Tb/Sm for white LEDs［J］. Materials Science and Engineering: B, 2022, 276: 115565.

[6] [6] MARES J A, NIKL M, NITSCH K, et al. A role of Gd3+ in scintillating processes in Tb-doped Na-Gd phosphate glasses［J］. Journal of Luminescence, 2001, 94/95: 321-324.

[7] [7] PAN Z, JAMES K, CUI A. Burger, et al. Terbium-activated lithium-lanthanum-aluminosilicate oxyfluoride scintillating glass and glass-ceramic［J］. Nuclear Instruments And Methods In Physics Research Section A, 2008, 594, 215.

[8] [8] FU Z Y, XU P B, YANG Y S, et al. Study on luminescnt properties of Ce3+ sensitized Tb3+ doped gadolinium borosilicate scintillating glass［J］. Journal of Luminescence, 2018, 196: 368-372.

[9] [9] XU P B, FU Z Y, FAN S F, et al. Study on the sensitization of Gd3+ on Ce3+/Tb3+ co-doped GBS scintillating glass［J］. Journal of Non-Crystalline Solids, 2018, 481: 441-446.

[10] [10] SUN X Y, YE Z P, WU Y T, et al. A simple and highly efficient method for synthesis of Ce3+-activated borogermanate scintillating glasses in air［J］. Journal of the American Ceramic Society, 2014, 97(11): 3388-3391.

[11] [11] SUN X Y, XIAO Z H, WU Y T, et al. Fast Ce3+-activated borosilicate glass scintillators prepared in air atmosphere［J］. Ceramics International, 2017, 43(3): 3401-3404.

[12] [12] SUN X Y, XIAO Z H, WU Y T, et al. Role of Al3+ on tuning optical properties of Ce3+-activated borosilicate scintillating glasses prepared in air［J］. Journal of the American Ceramic Society, 2018, 101(10): 4480-4485.

[13] [13] SENTHIL RAJA D, CHENG P Y, CHENG C C, et al. In-situ grown metal-organic framework-derived carbon-coated Fe-doped cobalt oxide nanocomposite on fluorine-doped tin oxide glass for acidic oxygen evolution reaction［J］. Applied Catalysis B: Environmental, 2022, 303: 120899.

[14] [14] YE G Q, FANG L Z, ZHOU X, et al. Tunable luminescence and energy transfer properties in novel fluoro-oxide glass ceramics containing KGd2F7: Dy3+/Tb3+ nanocrystals［J］. Materials Research Bulletin, 2023, 157: 112028.

[15] [15] LIU R W, CHEN M J, ZHU X R, et al. Luminescent properties and structure of Dy3+ doped germanosilicate glass［J］. Journal of Luminescence, 2020, 226: 117378.

[16] [16] WEN Z X, LI L J, HUANG W J, et al. Effect of Al powder on Tb3+-doped borogermanate glass for X-ray detection［J］. Journal of Luminescence, 2022, 250: 119095.

[17] [17] REISFELD R, GREENBERG E, VELAPOLDI R, et al. Luminescence quantum efficiency of Gd and Tb in borate glasses and the mechanism of energy transfer between them［J］. The Journal of Chemical Physics, 1972, 56(4): 1698-1705.

[18] [18] YAO G P, VALIEV D, STEPANOV S, et al. Steady state and time-resolved luminescence of Tb3+/Ce3+ doped ABS-BGP glasses［J］. Journal of Luminescence, 2019, 207: 310-315.