[1] D M RUBAT, H J KLEEBE, M M MÜLLER et al. Fifty years of research and development coming to fruition; unraveling the complex interactions during processing of transparent magnesium aluminate (MgAl2O4) spinel. Journal of the American Ceramic Society, 3341-3365(2013).
[2] K WAETZIG, A KRELL, R TRICE. The effect of composition on the optical properties and hardness of transparent Al-rich MgO·nAl2O3 spinel ceramics. Journal of the American Ceramic Society, 946-953(2015).
[3] J SANGHERA, S BAYYA, G VILLALOBOS et al. Transparent ceramics for high-energy laser systems. Optical Materials, 511-518(2011).
[4] J M PAPPAS, X Y DONG. Porosity characterization of additively manufactured transparent MgAl2O4 spinel by laser direct deposition. Ceramics International, 6745-6755(2020).
[5] J A SALEM, V SGLAVO. Transparent armor ceramics as spacecraft windows. Journal of the American Ceramic Society, 281-289(2013).
[6] A ROTHMAN, S KALABUKHOV, N SVERDLOV et al. The effect of grain size on the mechanical and optical properties of spark plasma sintering-processed magnesium aluminate spinel MgAl2O4. International Journal of Applied Ceramic Technology, 146-153(2014).
[7] M SOKOL, S KALABUKHOV, R SHNECK et al. Effect of grain size on the static and dynamic mechanical properties of magnesium aluminate spinel (MgAl2O4). Journal of the European Ceramic Society, 3417-3424(2017).
[8] V NECINA, W PABST. Grain growth of MgAl2O4 ceramics with LiF and NaF addition. Open Ceramics, 100078(2021).
[9] H ZHANG, H WANG, H GU et al. Preparation of transparent MgO·1.8Al2O3 spinel ceramics by aqueous gelcasting, presintering and hot isostatic pressing. Journal of the European Ceramic Society, 4057-4063(2018).
[10] J YAN, W YAN, Z CHEN et al. A strategy for controlling microstructure and mechanical properties of microporous spinel (MgAl2O4) aggregates from magnesite and Al(OH)3. Journal of Alloys and Compounds(2022).
[11] P ZHANG, P LIU, Y SUN et al. Microstructure and properties of transparent MgAl2O4 ceramic fabricated by aqueous gelcasting. Journal of Alloys and Compounds, 246-249(2016).
[12] H X WILLEMS, G D WITH, R METSELAAR. Thermodynamics of AlON III: stabilization of AlON with MgO. Journal of the European Ceramic Society, 43-49(1993).
[13] X ZONG, H WANG, H GU et al. A novel spinel-type Mg0.55Al2.36O3.81N0.19 transparent ceramic with infrared transmittance range comparable to c-plane sapphire. Scripta Materialia, 428-432(2020).
[14] X LIU, H WANG, B T TU et al. Highly transparent Mg0.27Al2.58O3.73N0.27ceramic prepared by pressureless sintering. Journal of the American Ceramic Society, 63-66(2014).
[15] Z ZHANG, H WANG, B T TU et al. Characterization and evaluation on mechanical property of Mg0.27Al2.58O3.73N0.27transparent ceramic. Journal of Inorganic Materials, 1006-1010(2018).
[16] X ZONG, H WANG, H GU et al. Highly transparent Mg0.27Al2.58O3.73N0.27ceramic fabricated by aqueous gelcasting, pressureless sintering, and post-HIP. Journal of the American Ceramic Society, 6507-6516(2019).
[18] A GRANON, P GOEURIOT, F THEVENOT et al. Reactivity in the Al2O3-AlN-MgO system. The MgAlON spinel phase. Journal of the European Ceramic Society, 365-370(1994).
[19] A KRELL, T HUTZLER, J KLIMKE. Transmission physics and consequences for materials selection, manufacturing, and applications. Journal of the European Ceramic Society, 207-221(2009).
[20] S H WEMPLE, M J DIDOMENICO. Behavior of the electronic dielectric constant in covalent and ionic materials. Physical Review B, 1338-1351(1971).
[21] B CAI, T KAINO, O SUGIHARA. Sulfonyl-containing polymer and its alumina nanocomposite with high Abbe number and high refractive index. Optical Materials Express, 1210-1216(2015).
[22] C A KLEIN. Flexural strength of infrared-transmitting window materials: bimodal Weibull statistical analysis. Optical Engineering, 1-10(2011).
[23] B DENG, D JIANG, J GONG. Is a three-parameter Weibull function really necessary for the characterization of the statistical variation of the strength of brittle ceramics. Journal of the European Ceramic Society, 2234-2242(2018).
[24] A KHALILI. Statistical properties of Weibull estimators. Journal of Materials Science, 6741-6752(1991).
[25] O TOKARIEV, L SCHNETTER, T BECK et al. Grain size effect on the mechanical properties of transparent spinel ceramics. Journal of the European Ceramic Society, 749-757(2013).
[26] J MALZBENDER, R W STEINBRECH. Threshold fracture stress of thin ceramic components. Journal of the European Ceramic Society, 247-252(2008).
[27] O TOKARIEV, R W STEINBRECH, L SCHNETTER et al. Micro- and macro-mechanical testing of transparent MgAl2O4 spinel. Journal of Materials Science, 4821-4826(2012).
[28] S R CHOI. Slow crack growth analysis of brittle materials with finite thickness subjected to constant stress-rate flexural loading. Journal of Materials Science, 3875-3882(1999).
[29] N D RAMOS, T M CAMPOS, I S PAZ et al. Microstructure characterization and SCG of newly engineered dental ceramics. Dental Materials, 870-878(2016).
[30] N EKATERINA, K KEYUR, C KIRA et al. Hall-Petch effect in binary and ternary alumina/zirconia/spinel composites. Journal of Materials Research and Technology, 823-832(2021).
[31] K SENTHIL, P BISWAS, R JOHNSON et al. Transparent ceramics for ballistic armor applications. Handbook of Advanced Ceramics and Composites, 435-457(2020).
[32] A KRELL, E STRASSBURGER, T HUTZLER et al. Single and polycrystalline transparent ceramic armor with different crystal structure. Journal of the American Ceramic Society, 2718-2721(2013).
[33] M J IQBAL, B ISMAIL, C RENTENBERGER et al. Modification of the physical properties of semiconducting MgAl2O4 by doping with a binary mixture of Co and Zn ions. Materials Research Bulletin, 2271-2277(2011).
[34] L REN, H WANG, B T TU et al. Investigation on composition- dependent properties of Mg5xAl23-5xO27+5xN5-5x (0≤x≤1): Part II. Mechanical properties via first-principles calculations combined with bond valence models. Journal of the European Ceramic Society, 4942-4950(2021).
