[1] Q SONG, Z H ZHANG, Z Y HU et al. Microstructure and mechanical properties of super-hard B4C ceramic fabricated by spark plasma sintering with (Ti3SiC2+Si) as sintering aid.. Ceramics International, 45, 8790(2019).
[2] S SONG, C BAO, B WANG. Effect of the addition of carbon fibres on the microstructure and mechanical properties of reaction bonded B4C/SiC composites. Journal of the European Ceramic Society, 36, 1905(2016).
[3] B M MOSHTAGHIOUN, F L CUMBRERA-HERNÁNDEZ, D GÓMEZ-GARCÍA et al. Effect of spark plasma sintering parameters on microstructure and room-temperature hardness and toughness of fine-grained boron carbide (B4C). Journal of the European Ceramic Society, 33, 361(2013).
[4] X ZHAO, J ZOU, W JI et al. Processing and mechanical properties of B4C-SiCw ceramics densified by spark plasma sintering. Journal of the European Ceramic Society, 42, 2004(2022).
[5] S WANG, S GAO, P XING et al. Pressureless liquid-phase sintering of B4C with MoSi2 as a sintering aid.. Ceramics International, 45, 13502(2019).
[6] P BARICK, D C JANA, N THIYAGARAJAN. Effect of particle size on the mechanical properties of reaction bonded boron carbide ceramics. Ceramics International, 39, 763(2013).
[7] A K SURI, C SUBRAMANIAN, J K SONBER et al. Synthesis and consolidation of boron carbide: a review. International Materials Reviews, 55, 4(2013).
[8] P FOROUGHI, Z CHENG. Understanding the morphological variation in the formation of B4C
[9] Y M Z AHMED, S M EL-SHEIKH, E M M EWAIS et al. Controlling the morphology and oxidation resistance of boron carbide synthesized
[12] A ALIZADEH, E TAHERI-NASSAJ, N EHSANI. Synthesis of boron carbide powder by a carbothermic reduction method. Journal of the European Ceramic Society, 24, 3227(2004).
[13] J KANANATHAN, A G N SOFIAH, M SAMYKANO et al. Influence of boric acid (H3BO3) concentration on the physical properties of electrochemical deposited nickel (Ni) nanowires. IOP Conference Series: Materials Science and Engineering(2017).
[14] S HAYUN, A WEIZMANN, M P DARIEL et al. Microstructural evolution during the infiltration of boron carbide with molten silicon. Journal of the European Ceramic Society, 30, 1007(2010).
[15] S HAYUN, N FRAGE, M P DARIEL. The morphology of ceramic phases in B
[16] S HAYUN, A WEIZMANN, M P DARIEL et al. The effect of particle size distribution on the microstructure and the mechanical properties of boron carbide-based reaction-bonded composites. International Journal of Applied Ceramic Technology, 6, 492(2009).
[17] C ZHANG, Q XIA, L HAN et al. Fabrication of carbon-coated boron carbide particle and its role in the reaction bonding of boron carbide by silicon infiltration. Journal of the European Ceramic Society, 42, 860(2022).
[18] Z F CHEN, Y C SU, Y B CHENG. Formation and sintering mechanisms of reaction bonded silicon carbide-boron carbide composites. Key Engineering Materials, 352: 207(2007).
[20] M PATEL, J SUBRAHMANYAM, V V B PRASAD et al. Processing and characterization of B4C-SiC-Si-TiB2 composites. Materials Science and Engineering: A, 527, 4109(2010).
[21] R CHAIM, M HEFETZ. Effect of grain size on elastic modulus and hardness of nanocrystalline ZrO2-3 wt%Y2O3 ceramic. Journal of Materials Sciences, 39, 3057(2004).
[22] F THÉVENOT. Boron carbide-a comprehensive review. Journal of the European Ceramic Society, 6, 205(1990).
[23] N DOWLING. Mechanical behavior of materials:engineering methods for deformation, fracture. and fatigue(2012).
[24] M BARSOUM, M W BARSOUM. Fundamentals of Ceramics(2002).
[25] S GUO, R I TODD. Quantitative optical fluorescence microprobe measurements of stresses around indentations in Al2O3 and Al2O3/SiC nanocomposites: the influence of depth resolution and specimen translucency. Acta Materialia, 59, 2637(2011).
[26] C ZHANG, H RU, W WANG et al. The role of infiltration temperature in the reaction bonding of boron carbide by silicon infiltration. Journal of the American Ceramic Society, 97, 3286(2014).
