[1] [1] RAMANA M V. Technical and social problems of nuclear waste［J］. Wiley Interdisciplinary Reviews: Energy and Environment, 2018, 7(4): e289.

[3] [3] WANG X, WU L, LI H D, et al. Preparation and characterization of SO-3 doped Barium borosilicate glassceramics containing zirconolite and barite phases［J］. Ceramics International, 2017, 43(1): 534539.

[4] [4] CHOUARD N, CAURANT D, MAJRUS O, et al. Effect of MoO3, Nd2O3, and RuO2 on the crystallization of sodalime aluminoborosilicate glasses［J］. Journal of Materials Science, 2015, 50(1): 219241.

[8] [8] WANG F, LIAO Q L, DAI Y Y, et al. Properties and vibrational spectra of iron borophosphate glasses/glassceramics containing lanthanum［J］. Materials Chemistry and Physics, 2015, 166: 215222.

[9] [9] WU K M, WANG F, LIAO Q L, et al. Synthesis of pyrochloreborosilicate glassceramics for immobilization of highlevel nuclear waste［J］. Ceramics International, 2020, 46(5): 60856094.

[12] [12] ZHU H Z, WANG F, LIAO Q L, et al. Synthesis and characterization of zirconolitesodium borosilicate glassceramics for nuclear waste immobilization［J］. Journal of Nuclear Materials, 2020, 532: 152026.

[13] [13] MCCLOY J S, RILEY B J, CRUM J, et al. Crystallization study of rare earth and molybdenum containing nuclear waste glass ceramics［J］. Journal of the American Ceramic Society, 2019, 102(9): 51495163.

[14] [14] PETERSON J A, CRUM J V, RILEY B J, et al. Synthesis and characterization of oxyapatite［Ca2Nd8(SiO4)6O2］and mixedalkalineearth powellite ［(Ca,Sr,Ba)MoO4］ for a glassceramic waste form［J］. Journal of Nuclear Materials, 2018, 510: 623634.

[15] [15] MATTHEW ASMUSSEN R, NEEWAY J J, KASPAR T C, et al. Corrosion behavior and microstructure influence of glassceramic nuclear waste forms［J］. CORROSION, 2017, 73(11): 13061319.

[16] [16] RAVIKUMAR R, GOPAL B, JENA H. Crystal chemical substitution at Ca and La sites in CaLa4(SiO4)3O to design the composition Ca1-xMxLa4-xREx(SiO4)3O for nuclear waste immobilization and its influence on the thermal expansion behavior［J］. Inorganic Chemistry, 2018, 57(11): 65116520.

[17] [17] KIM M, HEO J. Calciumborosilicate glassceramics wasteforms to immobilize rareearth oxide wastes from pyroprocessing［J］. Journal of Nuclear Materials, 2015, 467: 224228.

[19] [19] TONG Q, HUO J C, ZHANG X Q, et al. Study on structure and properties of La2O3doped basaltic glasses for immobilizing simulated lanthanides［J］. Materials (Basel, Switzerland), 2021, 14(16): 4709.

[20] [20] QUINTAS A, MAJRUS O, CAURANT D, et al. Crystallization of a rare earthrich aluminoborosilicate glass with varying CaO/Na2O ratio［J］. Journal of the American Ceramic Society, 2007, 90(3): 712719.

[24] [24] YU M, LIN J, ZHOU S B, et al. Solgel deposition and luminescent properties of oxyapatite Ca2(Y,Gd)8(SiO4)6O2 phosphor films doped with rare earth and lead ions［J］. Journal of Materials Chemistry, 2002, 12(1): 8691.

[25] [25] LI Q X, LI Z, HE C, et al. Understanding the solubility and crystallization of molybdenum in highsodium borosilicate glasses: effect of lanthanum oxide［J］. Journal of Radioanalytical and Nuclear Chemistry, 2022, 331(5): 21052115.

[26] [26] WIERZBICKAWIECZOREK M, GCKERITZ M, KOLITSCH U, et al. Crystallographic and spectroscopic investigations on nine metalrareearth silicates with the apatite structure type［J］. European Journal of Inorganic Chemistry, 2015, 2015(6): 948963.

[28] [28] ZHONG J S, CHEN D Q, XU H X, et al. Redemitting CaLa4(SiO4)3O: eu3+ phosphor with superior thermal stability and high quantum efficiency for warm wLEDs［J］. Journal of Alloys and Compounds, 2017, 695: 311318.

[30] [30] ZHENG B B, LUO Y F, LIAO H L, et al. Investigation of the crystallinity of suspension plasma sprayed hydroxyapatite coatings［J］. Journal of the European Ceramic Society, 2017, 37(15): 50175021.

[31] [31] LUO Z W, LEI W C, LIANG H Z, et al. Improving sealing properties of CaOSrOAl2O3SiO2 glass and glassceramics for solid oxide fuel cells: effect of La2O3 addition［J］. Ceramics International, 2020, 46(11): 1769817706.

[32] [32] ZHOU J J, LIAO Q L, WANG F, et al. Effect of Na2O and CaO on the solubility and crystallization of Mo in borosilicate glasses［J］. Journal of NonCrystalline Solids, 2021, 557: 120623.

[33] [33] CRUM J V, TURO L, RILEY B, et al. Multiphase glassceramics as a waste form for combined fission products: alkalis, alkaline earths, lanthanides, and transition metals［J］. Journal of the American Ceramic Society, 2012, 95(4): 12971303.

[34] [34] PATIL D S, KONALE M, GABEL M, et al. Impact of rare earth ion size on the phase evolution of MoO3containing aluminoborosilicate glassceramics［J］. Journal of Nuclear Materials, 2018, 510: 539550.

[35] [35] CHEN H, MARCIAL J, AHMADZADEH M, et al. Partitioning of rare earths in multiphase nuclear waste glassceramics［J］. International Journal of Applied Glass Science, 2020, 11(4): 660675.

[36] [36] KISSINGER R M, CRUM J V, RILEY B J. Singlecomponentatatime variation study for glassceramic waste forms［J］. Journal of the American Ceramic Society, 2021, 104(7): 37383749.

[37] [37] NEEWAY J J, ASMUSSEN R M, MCELROY E M, et al. Kinetics of oxyapatite ［Ca2Nd8(SiO4)6O2］ and powellite ［(Ca,Sr,Ba)MoO4］ dissolution in glassceramic nuclear waste forms in acidic, neutral, and alkaline conditions［J］. Journal of Nuclear Materials, 2019, 515: 227237.