Zhao: Mechanical and thermodynamic properties of ZrO 2, under high-pressure phase transition: A first-principles study. Farmer: The effect of the microstructure on mechanical properties of directionally solidified Al 2O 3/ZrO 2(Y 2O 3) eutectic. Fu: Microstructure and fracture toughness of A1 2O 3/Er 3A1 5O 12 eutectic ceramic prepared by laser zone remelting.
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Marshall: A critical evaluation of indentation techniques for measuring fracture toughness: I, direct crack measurements. Yang: Microstructure and mechanical properties of Al 2O 3/ZrO 2 eutectic ceramic composites prepared by explosion synthesis. Coutures: Effect of the melt temperature on the solidification process of liquid garnets Ln 3Al 5O 12 (Ln = Dy, Y, and Lu). Platzki: Thermochemical Data of Pure Substances (VCH, Weinheim, 1989). Ratke: A new ‘Jackson–Hunt’ model for monotectic composite growth. Faivre: Determination of the Jackson–Hunt constants of the In–In 2Bi eutectic alloy based on in situ observation of its solidification dynamics. Leibbrandt: Generalized ‘Jackson–Hunt’ model for eutectic solidification at low and large Peclet numbers and any binary eutectic phase diagram. Shitov: Nanoscaled grain boundaries and pores, microstructure and mechanical properties of translucent Yb: ceramics. Larrea: Microstructural stability and orientation relationships of directionally solidified Al 2O 3–Er 3Al 5O 12–ZrO 2, eutectic ceramics up to 1600 ☌. Sayir: Directional solidification of Al 2O 3–Al 2TiO 5 system. Balogh: Irradiation induced defect formation and phase transition in nanostructured ZrO 2. Herring: Effect of change of scale on sintering phenomena. Waku: Coupled growth of unidirectionally solidified Al 2O 3-YAG eutectic ceramics. Liu: Investigation on solid-liquid interface morphology during the A1 2O 3/MgA1 2O 4 eutectic ceramics solidification. Sverdina: Phase diagram of the system: Al 2O 3–ZrO 2. Huang: Effect of microwave sintering time on the flexural properties of the SiC/SiC composites. Baudín: CaZrO 3–MgO structural ceramics obtained by reaction sintering of dolomite–zirconia mixtures. Zhang: Densification behavior and microstructure evolution of hot-pressed SiC–SiBCN ceramics. Liu: Directional Solidification and Processing of Advanced Materials (Science Press, Beijing, 2008).ī. Chen: Fabrication of nanostructure Al 2O 3/ZrO 2, (Y 2O 3) eutectic by combustion synthesis melt-casting under ultra-high gravity. He: Preparation of Al 2O 3–ZrO 2–SiO 2, ceramic composites by high-gravity combustion synthesis. Lebbou: Microstructure and crystallography of Al 2O 3–Y 3Al 5O 12–ZrO 2, ternary eutectic oxide grown by the micro pulling down technique. Liu: Microstructure transformation from irregular eutectic to complex regular eutectic in directionally solidified Al 2O 3/GdAlO 3/ZrO 2 ceramics by laser floating zone melting. Hasebe: Temperature dependence of flexural strength and microstructure of Al 2O 3/Y 3Al 5O 12/ZrO 2 ternary melt growth composites. Kohtoku: The creep and thermal stability characteristics of a unidirectionally solidified eutectic composite. Kohtoku: High temperature strength and thermal stability of a unidirectionally solidified eutectic composite. Kohtoku: A ductile ceramic eutectic composite with high strength at 1873 K. Taheri: Microstructural evolution in creep aged of directionally solidified heat resistant HP-Nb steel alloyed with tungsten and nitrogen. The hardness of directionally solidified eutectic ceramics reaches 16.17 GPa and the fracture toughness reaches 4.76 MPa m 1/2, which are 1.7 times and 1.5 times of the presintered eutectic ceramic, respectively. In the directionally solidified Al 2O 3/ZrO 2 eutectic ceramics, Al 2O 3 phase is the matrix phase, and the ZrO 2 phase embedded in the Al 2O 3 phase mostly with the rod shape, and little with lamellar. And the saucer coil obtained a higher temperature gradient than the tubbiness coil for a fixed crucible wall maximum temperature, and the coil turn’s increase could increase the melting zone height in the induction zone melting process. And the bulk density increased first and then decreased with the molding pressure increase. The results show that increasing the sintering temperature could increase the presintered ceramic’s bulk density, while increasing sintering time had little effect. To prepare high quality large solidified Al 2O 3/ZrO 2 eutectic ceramic, the preparation processing of the presintered ceramic as a feed rod was investigated via experiments some parameters of the induction heating zone process were optimized via numerical modeling an Al 2O 3/ZrO 2 eutectic ceramic rod with a diameter 10 mm was prepared.
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