[2] A GOLDSTEIN, A SINGURINDI. Al₂O₃/TiC based metal cutting tools by microwave sintering followed by hot isostatic pressing. Journal of the American Ceramic Society, 1530(2010).

[4] A G EVANS, R M CANNON. Toughening of brittle solids by martensitic transformations. Acta Metallurgica, 761(1986).

[5] K F CAI, D S MCLACHLAN, N AXEN et al. Preparation, microstructures and properties of Al₂O₃-TiC composites. Ceramics International, 217(2002).

[6] E GEVORKYAN, M RUCKI, S PANCHENKO et al. Effect of SiC addition to Al₂O₃ ceramics used in cutting tools. Materials, 5195(2020).

[9] T XIA, Z MUNIR, Y TANG et al. Structure formation in the combustion synthesis of Al₂O₃/TiC composites. Journal of the American Ceramic Society, 507(2000).

[13] D WU, X YU, Z ZHAO. Direct additive manufacturing of TiC_p reinforced Al₂O₃-ZrO₂ eutectic functionally graded ceramics by laser directed energy deposition. Journal of the European Ceramic Society, 2718(2023).

[14] H LIU, H SU, Z SHEN et al. Research progress on ultrahigh temperature oxide eutectic ceramics by laser additive manufacturing. Journal of Inorganic Materials, 255(2022).

[15] D WU, C YU, Q WANG et al. Synchronous-hammer-forging- assisted laser directed energy deposition additive manufacturing of high-performance 316L samples. Journal of Materials Processing Technology, 117695(2022).

[18] D WU, J SHI, F NIU et al. Direct additive manufacturing of melt growth Al₂O₃-ZrO₂ functionally graded ceramics by laser directed energy deposition. Journal of the European Ceramic Society, 2957(2022).

[19] Y HUANG, D WU, D ZHAO et al. Process optimization of melt growth alumina/aluminum titanate composites directed energy deposition: effects of scanning speed. Additive Manufacturing, 35: 101210(2020).

[20] D WU, D ZHAO, Y HUANG et al. Shaping quality, microstructure, and mechanical properties of melt-grown mullite ceramics by directed laser deposition. Journal of Alloys and Compounds, 871: 159609(2021).

[21] H SU, J ZHANG, L LIU et al. Rapid growth and formation mechanism of ultrafine structural oxide eutectic ceramics by laser direct forming. Applied Physics Letters, 1174(2011).

[22] D ZHAO, D WU, F NIU et al. Heat treatment of melt-grown alumina ceramics with trace glass fabricated by laser directed energy deposition. Materials Characterization, 196: 112639(2023).

[23] Y HUANG, D WU, D ZHAO et al. Investigation of melt-growth alumina/aluminum titanate composite ceramics prepared by directed energy deposition. International Journal of Extreme Manufacturing, 3: 035101(2021).

[24] X WEI, M JIN, H YANG et al. Advances in 3D printing of magnetic materials: fabrication, properties, and their applications. Journal of Advanced Ceramics, 665(2022).

[28] W VOIGT. Ueber die beziehung zwischen den beiden elasticitätsconstanten isotroper körper. Annalen Der Physik, 573(1889).

[29] A REUSS. Berechnung der fleissgrenze von mischkristallen auf grund der plastizitats bedingung für einkrisalle. Zeitschrift für Angewandte Mathematik und Mechanik, 49(1929).

[30] P YUAN, D GU. Molten pool behaviour and its physical mechanism during selective laser melting of TiC/AlSi₁₀Mg nanocomposites: simulation and experiments. Journal of Physics D: Applied Physics, 035303(2015).

[31] P YUAN, D GU, D DAI. Particulate migration behavior and its mechanism during selective laser melting of TiC reinforced Al matrix nanocomposites. Materials and Design, 46(2015).

[33] P E GOINS, W E FRAZIER. A model of grain boundary complexion transitions and grain growth in yttria-doped alumina. Acta Materialia, 79(2020).

[35] Y W KIM, J G LEE. Pressureless sintering of alumina-titanium carbide composites. Journal of the American Ceramic Society, 1333(1989).

[36] K ISHIDA. Effect of grain size on grain boundary segregation. Journal of Alloys and Compounds, 244(1996).

[37] C D TERWILLIGER, Y M CHIANG. Size-dependent solute segregation and total solubility in ultrafine polycrystals: Ca in TiO₂. Acta Metallurgica Et Materialia, 319(1995).

[38] F NIU, D WU, S YAN et al. Process optimization for suppressing cracks in laser engineered net shaping of Al₂O₃ ceramics. The Journal of The Minerals, Metals & Materials Society, 557(2016).

[39] B R LAWN, T R WILSHAW. Fracture of brittle solids.

[40] D WU, X YU, Z ZHAO et al. One-step additive manufacturing of TiC_p reinforced Al₂O₃-ZrO₂ eutectic ceramics composites by laser directed energy deposition. Ceramics International, 12758.

[41] F F LANGE. Fracture mechanics of ceramics. Ceramurgia International, 142(1978).

[42] J K GUO. The Exploration on new approach of strengthening and toughening of ceramic materials. Journal of Inorganic Materials, 23(1998).

[43] M N AHSAN, R BRADLEY, A J PINKERTON. Microcomputed tomography analysis of intralayer porosity generation in laser direct metal deposition and its causes. Journal of Laser Applications, 807(2011).

[44] P A KOBRYN, E H MOORE. The effect of laser power and traverse speed on microstructure, porosity, and build height in laser-deposited Ti₆A1₄V. Scripta materialia, 299(2000).

[45] D F SUSAN, J D PUSKAR, J A BROOKS et al. Quantitative characterization of porosity in stainless steel LENS powders and deposits. Materials Characterization, 36(2006).

[46] F NIU, D WU, F LU et al. Microstructure and macro properties of Al₂O₃ ceramics prepared by laser engineered net shaping. Ceramics International, 14303(2018).

[47] I D FRANCISCO, R I MERINO, V M ORERA et al. Growth of Al₂O₃/ZrO₂(Y₂O₃) eutectic rods by the laser floating zone technique: effect of the rotation. Journal of the European Ceramic Society, 1341(2005).

[48] D WU, Y HUANG, F NIU et al. Effects of TiO₂ doping on microstructure and properties of directed laser deposition alumina/ aluminum titanate composites. Virtual and Physical Prototyping, 371(2019).

[49] D ZHAO, D WU, J SHI et al. Microstructure and mechanical properties of melt-grown alumina-mullite/glass composites fabricated by directed laser deposition. Journal of Advanced Ceramics, 75(2022).

[50] N J PETCH. The cleavage strength of polycrystals. Journal of the Iron and Steel Institute, 25(1953).

[51] E O HALL. The deformation and ageing of mild steel: III discussion of results. Proceedings of the Physical Society of London, 747(1951).