[1] [1] NIKL M, MIHOKOVá E, MARE? J A, et al. Traps and timing characteristics of LuAG: Ce3+ scintillator[J]. Phys Stat Sol (a), 2000, 181(1): R10-R12.

[2] [2] ZHU D Y, NIKL M, CHEWPRADITKUL W, et al. Development and prospects of garnet ceramic scintillators: A review[J]. J Adv Ceram, 2022, 11(12): 1825-1848.

[3] [3] NIKL M, YOSHIKAWA A, KAMADA K, et al. Development of LuAG-based scintillator crystals—A review[J]. Prog Cryst Growth Charact Mater, 2013, 59(2): 47-72.

[4] [4] PETROSYAN A G, OVANESYAN K L, SARGSYAN R V, et al. Bridgman growth and site occupation in LuAG: Ce scintillator crystals[J]. J Cryst Growth, 2010, 312(21): 3136-3142.

[5] [5] HU Z W, CHEN X P, DAI J W, et al. The influences of stoichiometry on the sintering behavior, optical and scintillation properties of Pr: LuAG ceramics[J]. J Eur Ceram Soc, 2018, 38(12): 4252-4259.

[6] [6] LIU S P, FENG X Q, NIKL M, et al. Fabrication and scintillation performance of nonstoichiometric LuAG: Ce ceramics[J]. J Am Ceram Soc, 2015, 98(2): 510-514.

[7] [7] ZORENKO Y, GORBENKO V, KONSTANKEVYCH I, et al. Scintillation properties of Lu3Al5O12: Ce single-crystalline films[J]. Nucl Instrum Meth Phys Res Sect A Accel Spectrometers Detect Assoc Equip, 2002, 486(1/2): 309-314.

[8] [8] ZORENKO Y, GORBENKO V, VOLOSHINOVSKII A, et al. Exciton-related luminescence in LuAG: Ce single crystals and single crystalline films[J]. Phys Stat Sol (a), 2005, 202(6): 1113-1119.

[9] [9] LIU S P, MARES J A, FENG X Q, et al. Towards bright and fast Lu3Al5O12: Ce, Mg optical ceramics scintillators[J]. Adv Opt Mater, 2016, 4(5): 731-739.

[10] [10] HU C, ZHANG L Y, ZHU R Y, et al. Hadron-induced radiation damage in LuAG: Ce scintillating ceramics[J]. IEEE Trans Nucl Sci, 2022, 69(2): 181-186.

[11] [11] KUNTZ J D, ROBERTS J J, HOUGH M, et al. Multiple synthesis routes to transparent ceramic lutetium aluminum garnet[J]. Scr Mater, 2007, 57(10): 960-963.

[12] [12] NIKL M, MIHOKOVA E, PEJCHAL J, et al. The antisite LuAl defect-related trap in Lu3Al5O12: Ce single crystal[J]. Phys Stat Sol (b), 2005, 242(14): R119-R121.

[13] [13] OGINO H, YOSHIKAWA A, NIKL M, et al. Suppression of defect related host luminescence in LuAG single crystals[J]. Phys Procedia, 2009, 2(2): 191-205.

[14] [14] LIU S P, FENG X Q, MARES J A, et al. Optical, luminescence and scintillation characteristics of non-stoichiometric LuAG: Ce ceramics[J]. J Lumin, 2016, 169: 72-77.

[15] [15] YANAGIDA T, FUJIMOTO Y, YOKOTA Y, et al. Scintillation properties of LuAG (Ce) ceramic and single crystalline scintillator[C]// IEEE Nuclear Science Symposuim & Medical Imaging Conference. Knoxville, TN, USA. IEEE, 2011: 1612-1614.

[16] [16] CHENG Z Q, WANG Y B, LIU X, et al. Component regulation and performance optimization of Al2O3-YAG: Ce composite ceramic phosphors for high-power laser lighting[J]. J Inorg Mater, 2022, 37(12): 1358.

[17] [17] LIU Q, WANG W L, DAI Z F, et al. Fabrication and long persistent luminescence of Ce3+-Cr3+ co-doped yttrium aluminum gallium garnet transparent ceramics[J]. J Rare Earths, 2022, 40(11): 1699-1705.

[18] [18] JI T, WANG T, LI H, et al. Ce3+-doped yttrium aluminum garnet transparent ceramics for high-resolution X-ray imaging[J]. Adv Opt Mater, 2022, 10(6): 2102056.

[19] [19] ZHU R Y. A very compact crystal shashlik electromagnetic calorimeter for future HEP experiments[J]. J Phys: Conf Ser, 2017, 928: 012015.

[20] [20] HU C, LI J A, YANG F, et al. LuAG ceramic scintillators for future HEP experiments[J]. Nucl Instrum Meth Phys Res Sect A Accel Spectrometers Detect Assoc Equip, 2020, 954: 161723.

[21] [21] NIKL M, KAMADA K, BABIN V, et al. Defect engineering in Ce-doped aluminum garnet single crystal scintillators[J]. Cryst Growth Des, 2014, 14(9): 4827-4833.

[22] [22] LIU S P, FENG X Q, ZHOU Z W, et al. Effect of Mg2+ co-doping on the scintillation performance of LuAG: Ce ceramics[J]. Phys Status Solidi RRL, 2014, 8(1): 105-109.

[23] [23] MA W Q, JIANG B X, CHEN S L, et al. A fast lutetium aluminum garnet scintillation ceramic with Ce3+ and Ca2+ co-dopants[J]. J Lumin, 2019, 216: 116728.

[24] [24] ZHU D Y, CHEN X P, BEITLEROVA A, et al. Influence of calcium doping concentration on the performance of Ce, Ca: LuAG scintillation ceramics[J]. J Eur Ceram Soc, 2022, 42(13): 6075-6084.

[25] [25] HU Z W, CHEN X P, LIU X, et al. Fabrication and scintillation properties of Pr: Lu3Al5O12 transparent ceramics from co-precipitated nanopowders[J]. J Alloys Compd, 2020, 818: 152885.

[26] [26] KAMADA K, NIKL M, KUROSAWA S, et al. Alkali earth co-doping effects on luminescence and scintillation properties of Ce doped Gd3Al2Ga3O12 scintillator[J]. Opt Mater, 2015, 41: 63-66.

[27] [27] BABIN V, HERMAN P, KUCERA M, et al. Effect of Mg2+ co-doping on the photo- and thermally stimulated luminescence of the (Lu, Gd)3(Ga, Al)5O12: Ce epitaxial films[J]. J Lumin, 2019, 215: 116608.

[28] [28] BABIN V, BOHá?EK P, JUREK K, et al. Dependence of Ce3+- related photo- and thermally stimulated luminescence characteristics on Mg2+ content in single crystals and epitaxial films of Gd3(Ga, Al)5O12: Ce, Mg[J]. Opt Mater, 2018, 83: 290-299.

[29] [29] MARTINAZZOLI L, NARGELAS S, BOHá?EK P, et al. Compositional engineering of multicomponent garnet scintillators:Towards an ultra-accelerated scintillation response[J]. Mater Adv, 2022, 3(17): 6842-6852.

[30] [30] XIA Z G, MEIJERINK A. Ce3+-doped garnet phosphors: composition modification, luminescence properties and applications[J]. Chem Soc Rev, 2017, 46(1): 275-299.

[31] [31] CHEN X P, HU Z W, CAO M Q, et al. Influence of cerium doping concentration on the optical properties of Ce, Mg: LuAG scintillation ceramics[J]. J Eur Ceram Soc, 2018, 38(9): 3246-3254.