[3] K WHITTLE. The Challenges of Nuclear Waste. Nuclear Materials Science, 21(2016).
[4] C CORKHILL, N HYATT. Nuclear Waste Management(2018).
[5] A E RINGWOOD, S E KESSON, N G WARE et al. Immobilisation of high level nuclear reactor wastes in SYNROC. Nature, 219-223(1979).
[6] A I ORLOVA, M I OJOVAN. Ceramic mineral waste-forms for nuclear waste immobilization. Materials, 2638-2683(2019).
[7] T S LIVSHITS. Stability of artificial ferrite garnets with actinides and lanthanoids in water solutions. Geology of Ore Deposits, 470-481(2008).
[8] J ZHANG, T S LIVSHITS, A A LIZIN et al. Irradiation of synthetic garnet by heavy ions and α-decay of 244Cm. Journal of Nuclear Materials, 137-142(2010).
[9] X GUO, A TAVAKOLI, S SUTTON et al. Cerium substitution in yttrium iron garnet: valence state, structure, and energetics. Chemistry of Materials, 1133-1143(2013).
[10] S GELLER. Crystal chemistry of the garnets. Zeitschrift fuer Kristallographie, 1-47(1967).
[11] S YUDINTSEV, M LAPINA, A PTASHKIN et al. Accommodation of uranium into the garnet structure. Materials Research Society Symposium Proceedings, 477-480(2002).
[12] I O GALUSKINA, E V GALUSKIN, T ARMBRUSTER et al. Elbrusite-(Zr)-a new uranian garnet from the Upper Chegem caldera, Kabardino-Balkaria, Northern Caucasus, Russia. American Mineralogist, 1172-1181(2010).
[13] T S YOUDINTSEVA. Study of synthetic ferrite garnets in context with the problem of immobilization of actinide wastes. Geology of Ore Deposits, 403-409(2005).
[14] R B BORADE, S E SHIRSATH, G VATS et al. Polycrystalline to preferred-100 texture phase transformation of yttrium iron garnet nanoparticles. Nanoscale Advances, 403-413(2019).
[15] S T ZHANG, L K WANG, B L XU et al. Rapid synthesis of Nd-doped Y3Fe5O12 garnet waste forms by microwave sintering. Ceramics International, 21924-21933(2021).
[16] MAKDAH M H EL, M H EL-DAKDOUKI, R MHANNA et al. Effects of neodymium substitution on the structural, optical, and magnetic properties of yttrium iron garnet nanoparticles. Applied Physics A, 304(2021).
[18] T DUAN, Y DING, S L LUO et al. Radionuclides from nature to nature: recent progress in immobilization of high level nuclear wastes in SYNROC. Journal of Inorganic Materials, 25-35(2021).
[19] D M STRACHAN. Results from long-term use of the MCC-1 static leach test method. Nuclear and Chemical Waste Management, 177-188(1983).
[20] S LI, J LIU, X YANG et al. Effect of phase evolution and acidity on the chemical stability of Zr1-xNdxSiO4-x/2 ceramics. Ceramics International, 3052-3058(2019).
[21] E BAÑOS-LÓPEZ, JESÚS F DE, C CORTÉS-ESCOBEDO et al. Enhancement in Curie temperature of yttrium iron garnet by doping with neodymium. Materials(2018).
[22] L VEGARD. Die konstitution der mischkristalle und die raumfüllung der atome. Zeitschrift für Physik, 17-26(1921).
[23] S LI, X YANG, J LIU et al. First-principles calculations and experiments for Ce4+ effects on structure and chemical stabilities of Zr1-xCexSiO4. Journal of Nuclear Materials, 276-283(2019).
[24] K ZHANG, Z HE, L PENG et al. Self-propagating synthesis of Y2-xNdxTi2O7 pyrochlore and its aqueous durability as nuclear waste form. Scripta Materialia, 300-303(2018).
[25] Y DING, X LONG, S PENG et al. Phase evolution and aqueous durability of Zr1-x-yCexNdyO2-y/2 ceramics designed to immobilize actinides with multi-valences. Journal of Nuclear Materials, 297-304(2017).
[26] X ZHAO, Y LI, Y TENG et al. The structure, sintering process, and chemical durability of Ce0.5Gd0.5PO4 ceramics. Ceramics International, 19718-19724(2018).
[27] Y DAN, K ZHANG, P LE et al. Solid-state reaction synthesis and chemical stability studies in Nd-doped zirconolite-rich ceramics. Journal of Rare Earths, 492-498(2018).
[28] F A CAPORUSCIO, B L SCOTT, H XU et al. Garnet nuclear waste forms-solubility at repository conditions. Nuclear Engineering and Design, 180-185(2014).
[29] S YUDINTSEV, A OSHEROVA, A DUBININ et al. Corrosion study of actinide waste forms with Garnet-type structure. Materials Research Society Symposium Proceedings, 1-8(2004).
[30] S L LUO, Z T XU, J LIU et al. The solubility, microstructure, and chemical durability of Ce-doped YIG ceramics designed as actinide waste forms. International Journal of Energy Research, 19883-19894(2022).
