[1] [1] MA S J, ZHOU C B, PAN J J, et al. Leachate from municipal solid waste landfills in a global perspective: characteristics, influential factors and environmental risks[J]. Journal of Cleaner Production, 2022, 333: 130264.

[2] [2] PARVIN F, TAREQ S M. Impact of landfill leachate contamination on surface and groundwater of Bangladesh: a systematic review and possible public health risks assessment[J]. Applied Water Science, 2021, 11(6): 100.

[3] [3] WANG S Y, LIU B, ZHANG Q, et al. Application of geopolymers for treatment of industrial solid waste containing heavy metals: state-of-the-art review[J]. Journal of Cleaner Production, 2023, 390: 136053.

[4] [4] SHAO Y Y, SHAO Y Q, ZHANG W Y, et al. Preparation of municipal solid waste incineration fly ash-based ceramsite and its mechanisms of heavy metal immobilization[J]. Waste Management, 2022, 143: 54-60.

[5] [5] SONG W F, CAO J W, WANG Z, et al. Glass-ceramics microstructure formation mechanism for simultaneous solidification of chromium and nickel from disassembled waste battery and chromium slag[J]. Journal of Hazardous Materials, 2021, 403: 123598.

[6] [6] NCUBE A, MATSIKA R, MANGORI L, et al. Moving towards resource efficiency and circular economy in the brick manufacturing sector in Zimbabwe[J]. Journal of Cleaner Production, 2021, 281: 125238.

[7] [7] LUO Z T, GUO J Y, LIU X H, et al. Preparation of ceramsite from lead-zinc tailings and coal gangue: physical properties and solidification of heavy metals[J]. Construction and Building Materials, 2023, 368: 130426.

[8] [8] FRANUS M, MADEJ J, PANEK R, et al. Effect of microwave radiation temperature and content of different solid waste on the microstructure and physicomechanical properties of lightweight aggregates[J]. Ceramics International, 2024, 50(2): 2871-2886.

[9] [9] LI X L, ZENG H, SUN N, et al. Preparation of lightweight ceramsite by stone coal leaching slag, feldspar, and pore-forming reagents[J]. Construction and Building Materials, 2023, 370: 130642.

[10] [10] SUN Y H, LI J S, CHEN Z, et al. Production of lightweight aggregate ceramsite from red mud and municipal solid waste incineration bottom ash: mechanism and optimization[J]. Construction and Building Materials, 2021, 287: 122993.

[11] [11] ZHOU Y, TANG Y Y, LIAO C Z, et al. Recent advances toward structural incorporation for stabilizing heavy metal contaminants: a critical review[J]. Journal of Hazardous Materials, 2023, 448: 130977.

[12] [12] DONDI M, CAPPELLETTI P, D’AMORE M, et al. Lightweight aggregates from waste materials: reappraisal of expansion behavior and prediction schemes for bloating[J]. Construction and Building Materials, 2016, 127: 394-409.

[13] [13] ZHANG J J, LIU B, ZHANG S G. A review of glass ceramic foams prepared from solid wastes: processing, heavy-metal solidification and volatilization, applications[J]. Science of the Total Environment, 2021, 781: 146727.

[14] [14] URIBE L, GIRALDO J D, VARGAS A. Effect of the operational conditions in the characteristics of ceramic foams obtained from quartz and sodium silicate[J]. Materials, 2020, 13(8): 1806.

[15] [15] LEE S, VANDERVEER B J, HRMA P, et al. Effects of heating rate, quartz particle size, viscosity, and form of glass additives on high-level waste melter feed volume expansion[J]. Journal of the American Ceramic Society, 2017, 100(2): 583-591.

[17] [17] XIAO T T, FAN X Y, ZHOU C Y, et al. Preparation of ultra-lightweight ceramsite from waste materials: using phosphate tailings as pore-forming agent[J]. Ceramics International, 2024, 50(9): 15218-15229.

[18] [18] PEI J N, PAN X L, QI Y F, et al. Preparation of ultra-lightweight ceramsite from red mud and immobilization of hazardous elements[J]. Journal of Environmental Chemical Engineering, 2022, 10(4): 108157.

[20] [20] WANG C, CHEN X X, DANG C, et al. Preparation of ceramsite from C&D waste and Baiyunebo tailings[J]. Procedia Environmental Sciences, 2016, 31: 211-217.

[21] [21] TANG P, JIANG S C, CHEN W, et al. Self-foaming high strength artificial lightweight aggregates derived from solid wastes: expansion mechanism and environmental impact[J]. Construction and Building Materials, 2023, 370: 130698.

[24] [24] SLIMANOU H, BAZIZ A, BOUZIDI N, et al. Thermal, physical, mechanical and microstructural properties of dredged sediment-based ceramic tiles as substituent of Kaolin[J]. Environmental Science and Pollution Research International, 2022, 29(18): 26792-26809.

[25] [25] WANG C Q, DUAN D Y, HUANG D M, et al. Lightweight ceramsite made of recycled waste coal gangue & municipal sludge: particular heavy metals, physical performance and human health[J]. Journal of Cleaner Production, 2022, 376: 134309.

[27] [27] WANG X R, JIN Y Y, WANG Z Y, et al. Development of lightweight aggregate from dry sewage sludge and coal ash[J]. Waste Management, 2009, 29(4): 1330-1335.

[28] [28] MYMRIN V, ALEKSEEV K, NAGALLI A, et al. Red ceramics enhancement by hazardous laundry water cleaning sludge[J]. Journal of Cleaner Production, 2016, 120: 157-163.

[29] [29] GONZLEZ-CORROCHANO B, ALONSO-AZCRATE J, RODAS M. Effect of thermal treatment on the retention of chemical elements in the structure of lightweight aggregates manufactured from contaminated mine soil and fly ash[J]. Construction and Building Materials, 2012, 35: 497-507.

[30] [30] TAHA Y, BENZAAZOUA M, MANSORI M, et al. Manufacturing of ceramic products using calamine hydrometallurgical processing wastes[J]. Journal of Cleaner Production, 2016, 127: 500-510.

[31] [31] LIU B, YANG Q W, ZHANG S G. Integrated utilization of municipal solid waste incineration fly ash and bottom ash for preparation of foam glass-ceramics[J]. Rare Metals, 2019, 38(10): 914-921.

[32] [32] LIU T Y, ZHANG J S, WU J Q, et al. The utilization of electrical insulators waste and red mud for fabrication of partially vitrified ceramic materials with high porosity and high strength[J]. Journal of Cleaner Production, 2019, 223: 790-800.

[33] [33] LIU T Y, XIE Y X, GUO X G, et al. The role and stabilization behavior of heavy metal ions in eco-friendly porous semi-vitrified ceramics for construction application[J]. Journal of Cleaner Production, 2021, 292: 125855.

[34] [34] REN Y H, REN Q, WU X L, et al. Recycling of solid wastes ferrochromium slag for preparation of eco-friendly high-strength spinel-corundum ceramics[J]. Materials Chemistry and Physics, 2020, 239: 122060.

[35] [35] SHAO Y Y, TIAN C, KONG W J, et al. Co-utilization of zinc contaminated soil and red mud for high-strength ceramsite: preparation, zinc immobilization mechanism and environmental safety risks[J]. Process Safety and Environmental Protection, 2023, 170: 491-497.

[36] [36] GAO W B, JIAN S W, LI B D, et al. Solidification of zinc in lightweight aggregate produced from contaminated soil[J]. Journal of Cleaner Production, 2020, 265: 121784.

[37] [37] ZHANG J J, LIU B, ZHAO S Z, et al. Preparation and characterization of glass ceramic foams based on municipal solid waste incineration ashes using secondary aluminum ash as foaming agent[J]. Construction and Building Materials, 2020, 262: 120781.

[38] [38] DENG S C, LI C R, GUO H W, et al. Crystallization characteristics, microstructural evolution, and Cr migration mechanism of glass-ceramics synthesized entirely from low-carbon ferrochromium slag and waste glass[J]. Journal of Hazardous Materials, 2023, 445: 130621.

[39] [39] YUAN Z S, CAI G K, GAO L F, et al. The physical encapsulation and chemical fixation of Zn during thermal treatment process of municipal solid waste incineration (MSWI) fly ash[J]. Waste Management, 2023, 166: 203-210.

[40] [40] DENG L B, YAO B, LU W W, et al. Effect of SiO2/Al2O3 ratio on the crystallization and heavy metal immobilization of glass ceramics derived from stainless steel slag[J]. Journal of Non-Crystalline Solids, 2022, 593: 121770.

[41] [41] ZOU W T, ZHANG W H, PI Y L, et al. Effect of sintering temperature on solidification and migration of non-volatile and volatile heavy metals in glass-ceramic[J]. Ceramics International, 2022, 48(4): 5040-5053.

[42] [42] HOSSAIN S S, YADAV S, MAJUMDAR S, et al. A comparative study of physico-mechanical, bioactivity and hemolysis properties of pseudo-wollastonite and wollastonite glass-ceramic synthesized from solid wastes[J]. Ceramics International, 2020, 46(1): 833-843.

[43] [43] LIU J L, PENG H L, PENG H N, et al. Production of glass-ceramics from MSW-fly ash and Dexing copper mine-tailing: crystallization kinetics, structure, properties and immobilization of heavy metals[J]. Ceramics International, 2023, 49(22): 35428-35437.

[44] [44] DU Y S, GUO Y H, WANG G Y, et al. Preparation of glass-ceramics from blast furnace slag and its heavy metal curing properties[J]. Journal of Material Cycles and Waste Management, 2023, 25(5): 3081-3092.

[45] [45] SZUMERA M, WACAWSKA I, SUOWSKA J. Influence of CuO and ZnO addition on the multicomponent phosphate glasses: spectroscopic studies[J]. Journal of Molecular Structure, 2016, 1114: 78-83.

[46] [46] GUI H, LI C, LIN C W, et al. Glass forming, crystallization, and physical properties of MgO-Al2O3-SiO2-B2O3 glass-ceramics modified by ZnO replacing MgO[J]. Journal of the European Ceramic Society, 2019, 39(4): 1397-1410.

[47] [47] MOCIOIU O C, POPA M, NEACSU E I, et al. Correlation of structural units and chemical stability in SiO2-PbO-Na2O ternary glasses: spectroscopic methods[J]. Journal of Non-Crystalline Solids, 2013, 361: 130-141.

[48] [48] TAHA Y, BENZAAZOUA M, EDAHBI M, et al. Leaching and geochemical behavior of fired bricks containing coal wastes[J]. Journal of Environmental Management, 2018, 209: 227-235.

[49] [49] NAZARI A M, RADZINSKI R, GHAHREMAN A. Review of arsenic metallurgy: treatment of arsenical minerals and the immobilization of arsenic[J]. Hydrometallurgy, 2017, 174: 258-281.

[50] [50] ZHU R B, MA G J, CAI Y S, et al. Ceramic tiles with black pigment made from stainless steel plant dust: physical properties and long-term leaching behavior of heavy metals[J]. Journal of the Air & Waste Management Association, 2016, 66(4): 402-411.

[51] [51] ZHANG C, WANG G F, XU F J, et al. Ceramsite made from remediated soil: a risk assessment of its potential role serving as urban street cushion[J]. Bulletin of Environmental Contamination and Toxicology, 2023, 111(1): 15.

[52] [52] MARANGONI M, NAIT-ALI B, SMITH D S, et al. White sintered glass-ceramic tiles with improved thermal insulation properties for building applications[J]. Journal of the European Ceramic Society, 2017, 37(3): 1117-1125.

[53] [53] ZHENG W K, HE D Y, LI H, et al. The preparation and properties of a shell structure ceramsite[J]. Materials, 2020, 13(4): 1009.

[54] [54] LI H, YANG Y X, ZHENG W K, et al. Immobilization of high concentration hexavalent chromium via core-shell structured lightweight aggregate: a promising soil remediation strategy[J]. Chemical Engineering Journal, 2020, 401: 126044.

[56] [56] ACHIOU B, ELOMARI H, BOUAZIZI A, et al. Manufacturing of tubular ceramic microfiltration membrane based on natural pozzolan for pretreatment of seawater desalination[J]. Desalination, 2017, 419: 181-187.

[57] [57] SHEN C, WANG Y J, XU J H, et al. Chitosan supported on porous glass beads as a new green adsorbent for heavy metal recovery[J]. Chemical Engineering Journal, 2013, 229: 217-224.

[58] [58] CHEN N, ZHANG Z Y, FENG C P, et al. Preparation and characterization of porous granular ceramic containing dispersed aluminum and iron oxides as adsorbents for fluoride removal from aqueous solution[J]. Journal of Hazardous Materials, 2011, 186(1): 863-868.

[59] [59] LAMRI Y, BENZERGA R, AYADI A, et al. Glass foam composites based on tire’s waste for microwave absorption application[J]. Journal of Non-Crystalline Solids, 2020, 537: 120017.

[60] [60] PI Y L, ZHANG W H, ZHANG Y S, et al. Migration and transformation of heavy metals in glass-ceramics and the mechanism of stabilization[J]. Ceramics International, 2021, 47(17): 24663-24674.

[61] [61] FANG Y N, PAGE S J, REES G J, et al. Crystal chemistry of vanadium-bearing ellestadite waste forms[J]. Inorganic Chemistry, 2018, 57(15): 9122-9132.

[62] [62] JACOBSSON T J, PAZOKI M, HAGFELDT A, et al. Goldschmidt’s rules and strontium replacement in lead halogen perovskite solar cells: theory and preliminary experiments on CH3NH3SrI3[J]. The Journal of Physical Chemistry C, 2015, 119(46): 25673-25683.

[64] [64] LIAO C Z, TANG Y Y, LEE P H, et al. Detoxification and immobilization of chromite ore processing residue in spinel-based glass-ceramic[J]. Journal of Hazardous Materials, 2017, 321: 449-455.

[65] [65] WANG G H, UM W, KIM D S, et al. 99Tc immobilization from off-gas waste streams using nickel-doped iron spinel[J]. Journal of Hazardous Materials, 2019, 364: 69-77.

[66] [66] LI M J, SU P, GUO Y N, et al. Effects of SiO2, Al2O3 and Fe2O3 on leachability of Zn, Cu and Cr in ceramics incorporated with electroplating sludge[J]. Journal of Environmental Chemical Engineering, 2017, 5(4): 3143-3150.

[67] [67] SU M H, LIAO C Z, CHAN T S, et al. Incorporation of cadmium and nickel into ferrite spinel solid solution: X-ray diffraction and X-ray absorption fine structure analyses[J]. Environmental Science & Technology, 2018, 52(2): 775-782.

[68] [68] CONTE S, ZANELLI C, ARDIT M, et al. Phase evolution during reactive sintering by viscous flow: disclosing the inner workings in porcelain stoneware firing[J]. Journal of the European Ceramic Society, 2020, 40(4): 1738-1752.

[69] [69] KIM M, HA M G, UM W, et al. Relationship between leaching behavior and glass structure of calcium-aluminoborate waste glasses with various La2O3 contents[J]. Journal of Nuclear Materials, 2020, 539: 152331.

[70] [70] ARDIT M, ZANELLI C, CONTE S, et al. Ceramisation of hazardous elements: benefits and pitfalls of the inertisation through silicate ceramics[J]. Journal of Hazardous Materials, 2022, 423: 126851.

[71] [71] MACIAG B J, BRENAN J M. Speciation of arsenic and antimony in basaltic magmas[J]. Geochimica et Cosmochimica Acta, 2020, 276: 198-218.

[72] [72] ALLALI D, BOUHEMADOU A, AL SAFI E M A, et al. Electronic and optical properties of the SiB2O4 (B=Mg, Zn, and Cd) spinel oxides: an ab initio study with the Tran-Blaha-modified Becke-Johnson density functional[J]. Physica B: Condensed Matter, 2014, 443: 24-34.

[73] [73] MA W, TANG Y Y, WU P F, et al. Sewage sludge incineration ash for coimmobilization of lead, zinc and copper: mechanisms of metal incorporation and competition[J]. Waste Management, 2019, 99: 102-111.

[74] [74] WANG X X, ZHANG L, ZHU K Y, et al. Distribution and chemical species transition behavior of chlorides in municipal solid waste incineration fly ash during the pressure-assisted sintering treatment[J]. Chemical Engineering Journal, 2021, 415: 128873.

[75] [75] WANG G W, NING X N, LU X W, et al. Effect of sintering temperature on mineral composition and heavy metals mobility in tailings bricks[J]. Waste Management, 2019, 93: 112-121.

[76] [76] ZHOU Y, LIAO C Z, ZHOU Z Y, et al. Effectively immobilizing lead through a melanotekite structure using low-temperature glass-ceramic sintering[J]. Dalton Transactions (Cambridge, England), 2019, 48(12): 3998-4006.

[77] [77] WANG J Q, HAN F L, YANG B G, et al. A study of the solidification and stability mechanisms of heavy metals in electrolytic manganese slag-based glass-ceramics[J]. Frontiers in Chemistry, 2022, 10: 989087.

[78] [78] GUO L, HU Y C, LEI Y, et al. Vitrification of petrochemical sludge for rapid, facile, and sustainable fixation of heavy metals[J]. Journal of Environmental Chemical Engineering, 2022, 10(6): 108812.

[79] [79] ZHAN X Y, WANG Y, WANG L A, et al. Migration, solidification/stabilization mechanism of heavy metal in lightweight ceramisite from co-sintering fly ash and electrolytic manganese residue[J]. Process Safety and Environmental Protection, 2023, 173: 485-494.

[80] [80] KUO Y M, LIN T C, TSAI P J. Effect of SiO2 on immobilization of metals and encapsulation of a glass network in slag[J]. Journal of the Air & Waste Management Association (1995), 2003, 53(11): 1412-1416.

[81] [81] LI C T, LEE W J, HUANG K L, et al. Vitrification of chromium electroplating sludge[J]. Environmental Science & Technology, 2007, 41(8): 2950-2956.

[82] [82] CORONADO M, SEGADES A M, ANDRS A. Using mixture design of experiments to assess the environmental impact of clay-based structural ceramics containing foundry wastes[J]. Journal of Hazardous Materials, 2015, 299: 529-539.

[83] [83] LUO Y L, WANG F, LIAO Q L, et al. Effect of TiO2 on crystallization kinetics, microstructure and properties of building glass-ceramics based on granite tailings[J]. Journal of Non-Crystalline Solids, 2021, 572: 121092.

[84] [84] RILEY C M. Relation of chemical properties to the bloating of clays[J]. Journal of the American Ceramic Society, 1951, 34(4): 121-128.

[85] [85] CHIOU I J, WANG K S, CHEN C H, et al. Lightweight aggregate made from sewage sludge and incinerated ash[J]. Waste Management, 2006, 26(12): 1453-1461.

[86] [86] WEI Y L, KO G W. Recycling steel wastewater sludges as raw materials for preparing lightweight aggregates[J]. Journal of Cleaner Production, 2017, 165: 905-916.

[87] [87] LIU Y P, WAN W H, YANG F H, et al. Performance of glass-ceramic-based lightweight aggregates manufactured from waste glass and muck[J]. Ceramics International, 2022, 48(16): 23468-23480.

[88] [88] AYATI B, FERRNDIZ-MAS V, NEWPORT D, et al. Use of clay in the manufacture of lightweight aggregate[J]. Construction and Building Materials, 2018, 162: 124-131.

[89] [89] BALAPOUR M, THWAY T, RAO R, et al. A thermodynamics-guided framework to design lightweight aggregate from waste coal combustion fly ash[J]. Resources, Conservation and Recycling, 2022, 178: 106050.

[90] [90] LIU Z, GUO R X, PAN T H, et al. Preparation of ceramsite from low-silicon red mud (LSRM): effects of Si-Al ratio and sintering temperature[J]. Ceramics International, 2023, 49(21): 34191-34204.

[91] [91] WEI Y L, CHENG S H, OU K T, et al. Effect of calcium compounds on lightweight aggregates prepared by firing a mixture of coal fly ash and waste glass[J]. Ceramics International, 2017, 43(17): 15573-15579.

[92] [92] WEI Y L, KUO P J, YIN Y Z, et al. Co-sintering oyster shell with hazardous steel fly ash and harbor sediment into construction materials[J]. Construction and Building Materials, 2018, 172: 224-232.

[93] [93] LONG Y Y, PU K, YANG Y Q, et al. Preparation of high-strength ceramsite from municipal solid waste incineration fly ash and clay based on CaO-SiO2-Al2O3 system[J]. Construction and Building Materials, 2023, 368: 130492.

[94] [94] TAHA Y, BENZAAZOUA M, MANSORI M, et al. Recycling feasibility of glass wastes and calamine processing tailings in fired bricks making[J]. Waste and Biomass Valorization, 2017, 8(5): 1479-1489.

[95] [95] ZHANG Z K, WANG J, LIU L N, et al. Preparation of additive-free glass-ceramics from MSW incineration bottom ash and coal fly ash[J]. Construction and Building Materials, 2020, 254: 119345.

[96] [96] LI B Q, GUO Y P, FANG J Z. Effect of MgO addition on crystallization, microstructure and properties of glass-ceramics prepared from solid wastes[J]. Journal of Alloys and Compounds, 2021, 881: 159821.

[97] [97] ZHANG Z, ZHAO M, ZHANG Y, et al. The solidification and volatilization behavior of heavy metal ions in ceramic proppant made from fly ash[J]. Ceramics International, 2023, 49(17): 28326-28336.

[98] [98] WANG C S, REN X Y, DIAO Q W, et al. Sound absorption performance of a triple-hole structure in green ceramsite concrete for high-speed-railway sound barriers: experiments and neural network modeling[J]. Case Studies in Construction Materials, 2023, 18: e01980.

[99] [99] ZHAO L N, HU M, MUSLIM H, et al. Co-utilization of lake sediment and blue-green algae for porous lightweight aggregate (ceramsite) production[J]. Chemosphere, 2022, 287: 132145.

[101] [101] LIU T Y, LIU P, GUO X G, et al. Preparation, characterization and discussion of glass ceramic foam material: analysis of glass phase, fractal dimension and self-foaming mechanism[J]. Materials Chemistry and Physics, 2020, 243: 122614.

[102] [102] DUCMAN V, KORAT L, LEGAT A, et al. X-ray micro-tomography investigation of the foaming process in the system of waste glass-silica mud-MnO2[J]. Materials Characterization, 2013, 86: 316-321.

[103] [103] DE GENNARO R, LANGELLA A, D’AMORE M, et al. Use of zeolite-rich rocks and waste materials for the production of structural lightweight concretes[J]. Applied Clay Science, 2008, 41(1/2): 61-72.

[104] [104] KANG M A, KANG S. Effect of activated carbon on bloating properties of artificial lightweight aggregates containing coal reject ash and bottom ash[J]. Journal of the Korean Crystal Growth and Crystal Technology, 2013, 23(4): 201-206.

[105] [105] XI X A, SHUI A Z, LI Y F, et al. Effects of magnesium oxychloride and silicon carbide additives on the foaming property during firing for porcelain ceramics and their microstructure[J]. Journal of the European Ceramic Society, 2012, 32(12): 3035-3041.

[106] [106] NADESAN M S, DINAKAR P. Structural concrete using sintered flyash lightweight aggregate: a review[J]. Construction and Building Materials, 2017, 154: 928-944.

[107] [107] JAROSLAV S R B, ZDENKA R. Pelletization of fines, developments in mineral processing[J]. The Netherlands: Elsevier Science Publishers BV, 1988, 7: 292-296.

[108] [108] MANIKANDAN R, RAMAMURTHY K. Influence of fineness of fly ash on the aggregate pelletization process[J]. Cement and Concrete Composites, 2007, 29(6): 456-464.

[109] [109] RAMAMURTHY K, HARIKRISHNAN K I. Influence of binders on properties of sintered fly ash aggregate[J]. Cement and Concrete Composites, 2006, 28(1): 33-38.

[110] [110] LEIVA C, RODRIGUEZ-GALN M, ARENAS C, et al. A mechanical, leaching and radiological assessment of fired bricks with a high content of fly ash[J]. Ceramics International, 2018, 44(11): 13313-13319.

[111] [111] HU N Y, LV Y F, LUO B Y, et al. Preparation and performance of porous ceramsite for Ag+ removal in sewage treatment with total phosphorus tailings[J]. Journal of Cleaner Production, 2023, 413: 137515.

[112] [112] JIA G H, WANG Y L, YANG F L, et al. Preparation of CFB fly ash/sewage sludge ceramsite and the morphological transformation and release properties of sulfur[J]. Construction and Building Materials, 2023, 373: 130864.

[114] [114] MI H C, YI L S, WU Q, et al. Preparation of high-strength ceramsite from red mud, fly ash, and bentonite[J]. Ceramics International, 2021, 47(13): 18218-18229.

[115] [115] KIM Y, RYU Y W, JANG C S, et al. A study on the black core formation of artificial lightweight aggregates at various sintering atmospheres[J]. Journal of the Korean Crystal Growth and Crystal Technology, 2009, 19(6): 318-323.

[116] [116] HE F, TIAN S S, WEN J, et al. Microstructure and mechanical properties of ceramics prepared under simulated oxygen-enriched or oxy-fuel atmosphere[J]. Ceramics International, 2015, 41(2): 2779-2784.

[117] [117] CHEN R, GUO H, HUANG Z, et al. Influence of sintering atmosphere on phase, microstructure and mechanical properties of Li4Si0.7Ti0.3O4 tritium breeding ceramics[J]. Ceramics International, 2023, 49(5): 7623-7629.