Fabrication, microstructure and mechanical properties of (Me1/3Hf1/3Nb1/3)B2(Me=Ti, Zr, Ta) ceramics
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摘要: 以采用硼热/碳热还原反应自合成的(Me1/3Hf1/3Nb1/3)B2 (Me=Ti, Zr, Ta) 为原料,通过放电等离子烧结制备了(Me1/3Hf1/3Nb1/3)B2陶瓷,系统研究了其相组成、致密度、显微结构和力学性能。结果表明,(Ti1/3Hf1/3Nb1/3)B2和(Zr1/3Hf1/3Nb1/3)B2陶瓷具有较高的致密度(~98%),而(Ta1/3Hf1/3Nb1/3)B2陶瓷的致密度较低(~93%)。(Ti1/3Hf1/3Nb1/3)B2的晶粒较粗,而(Zr1/3Hf1/3Nb1/3)B2和(Ta1/3Hf1/3Nb1/3)B2的晶粒相对较小,并且在(Ta1/3Hf1/3Nb1/3)B2中Nb元素出现局部偏析。(Ti1/3Hf1/3Nb1/3)B2陶瓷具有较优异的力学性能,硬度和韧性分别为(20.08±0.81) GPa和(2.52±0.15) MPa·m1/2,而(Zr1/3Hf1/3Nb1/3)B2陶瓷的力学性能较差,硬度和断裂韧性分别为(17.21±0.63) GPa和(1.50±0.18) MPa·m1/2。Abstract: With (Me1/3Hf1/3Nb1/3)B2 (Me=Ti, Zr, Ta) powders self-synthesized via boron/carbothermal reduction, (Me1/3Hf1/3Nb1/3)B2 ceramics were prepared by spark plasma sintering (SPS), and their phase composition, relative density, microstructure and mechanical properties were investigated systematically. The result reveals that (Ti1/3Hf1/3Nb1/3)B2 and (Zr1/3Hf1/3Nb1/3)B2 possess the high relative density (~98%), while (Ta1/3Hf1/3Nb1/3)B2 has the lowest relative density (~93%). (Ti1/3Hf1/3Nb1/3)B2 possesses relatively coarse grains, while (Zr1/3Hf1/3Nb1/3)B2 and (Ta1/3Hf1/3Nb1/3)B2 possess relatively fine grains and Nb segregation is found in (Ta1/3Hf1/3Nb1/3)B2. (Ti1/3Hf1/3Nb1/3)B2 shows the most excellent mechanical properties with the Vickers hardness and fracture toughness of (20.08±0.81) GPa and (2.52±0.15) MPa·m1/2, respectively, whereas the mechanical properties of (Zr1/3Hf1/3Nb1/3)B2 are inferior, with hardness and fracture toughness of (17.21±0.63) GPa and (1.50±0.18) MPa·m1/2, respectively.
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图 1 2000℃烧结(Me1/3Hf1/3Nb1/3)B2 陶瓷的XRD图谱:(a) (Ti1/3Hf1/3Nb1/3)B2;(b) (Zr1/3Hf1/3Nb1/3)B2;(c) (Ta1/3Hf1/3Nb1/3)B2
Figure 1. XRD patterns of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃: (a) (Ti1/3Hf1/3Nb1/3)B2; (b) (Zr1/3Hf1/3Nb1/3)B2; (c) (Ta1/3Hf1/3Nb1/3)B2
图 2 2000℃烧结(Me1/3Hf1/3Nb1/3)B2 陶瓷SEM图像和相应的能谱元素图:(a) (Ti1/3Hf1/3Nb1/3)B2;(b) (Zr1/3Hf1/3Nb1/3)B2;(c) (Ta1/3Hf1/3Nb1/3)B2
Figure 2. SEM images and the corresponding EDS elemental mappings of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃: (a) (Ti1/3Hf1/3Nb1/3)B2; (b) (Zr1/3Hf1/3Nb1/3)B2; (c) (Ta1/3Hf1/3Nb1/3)B2
图 3 2000℃烧结(Me1/3Hf1/3Nb1/3)B2陶瓷材料腐蚀的SEM图像:(a) (Ti1/3Hf1/3Nb1/3)B2;(b) (Zr1/3Hf1/3Nb1/3)B2;(c) (Ta1/3Hf1/3Nb1/3)B2
Figure 3. SEM images of the polished surface of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃ after acid etching: (a) (Ti1/3Hf1/3Nb1/3)B2; (b) (Zr1/3Hf1/3Nb1/3)B2; (c) (Ta1/3Hf1/3Nb1/3)B2
图 4 2000℃烧结(Me1/3Hf1/3Nb1/3)B2 陶瓷材料的裂纹扩展图像:(a) (Ti1/3Hf1/3Nb1/3)B2;(b) (Zr1/3Hf1/3Nb1/3)B2;(c) (Ta1/3Hf1/3Nb1/3)B2
Figure 4. Crack propagation images of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃: (a) (Ti1/3Hf1/3Nb1/3)B2; (b) (Zr1/3Hf1/3Nb1/3)B2; (c) (Ta1/3Hf1/3Nb1/3)B2
表 1 2000℃烧结(Me1/3Hf1/3Nb1/3)B2陶瓷的晶胞参数、相对密度、晶粒尺寸与力学性能
Table 1. Lattice parameters, relative density, grain size and mechanical properties of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃
Code a/nm c/nm Relative
density/%Grain
size/μmHardness/
GPaFracture toughness/
(MPa·m1/2)(Ti1/3Hf1/3Nb1/3)B2 0.30919 0.33423 98.02 1.97±0.47 20.08±0.81 2.52±0.15 (Zr1/3Hf1/3Nb1/3)B2 0.31346 0.34384 98.35 1.67±0.43 17.21±0.63 1.50±0.18 (Ta1/3Hf1/3Nb1/3)B2 0.31076 0.33481 92.87 1.55±0.38 19.29±0.73 2.43±0.14 Notes: a and c—Lattice parameters of (Me1/3Hf1/3Nb1/3)B2 ceramics sintered at 2000℃. 
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