Synthesis and Consolidation of Composite Materials in the SiC–Si3N4–Si2N2O System

IF 0.9 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
N. K. Davydchuk, M. P. Gadzyra, Y. G. Tymoshenko, M. O. Pinchuk
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Abstract

Features peculiar to the synthesis of SiC–Si3N4–Si2N2O composite powder with a controlled content of silicon carbide, nitride, and oxynitride phases, as well as the structure and properties of hot-pressed ceramics produced from this powder, were examined. The optimal composition of the synthesized SiC–Si3N4–Si2N2O powder was achieved by heating a 1 : 3 mixture of thermally expanded graphite (TEG) and silicon up to 1200°C in air. The interaction of TEG with fine silicon at 1200°C led to the formation of a solid solution of carbon in silicon carbide, accompanied by heat release. The generated heat increased temperature within localized volumes of the TEG cellular structure to a level where air nitrogen facilitated the development of silicon nitride and oxynitride and an amorphous phase. The amorphous phase crystallized as the interaction time increased to 2.5 h. The duration of the process influenced the final distribution of the phases, formed with the participation of CO, SiO, and air nitrogen. The microstructure of the synthesized powder was characterized by a general agglomerated state, resulting from rod and plate forms of Si3N4 and Si2N2O. Hot pressing of the synthesized SiC–Si3N4–Si2N2O composite powder with Al2O3 and Y2O3 activators yielded superfine ceramics, possessing enhanced hardness and fracture toughness (HV10 = 20.7 GPa and KIc = 6.5 MPa · m1/2). The structure of the ceramics sintered at 2000°C differed from those sintered at 1850°C, primarily by higher density and average grain size. The superfine state significantly influenced the abrasive wear resistance of the ceramics in dry friction conditions. The linear wear index of a sample with an average size of structural elements varying from 0.2 to 1.5 μm was 111 μm/km at a sliding speed of 1 m/sec under a load of 0.2 MPa. This was significantly lower than the linear wear index of industrial ceramics of reaction-sintered silicon carbide (RSSC), which was 232.4 μm/km.

Abstract Image

Abstract Image

SiC-Si3N4-Si2N2O 体系复合材料的合成与固结
研究了碳化硅、氮化硅和氧氮化硅相含量可控的 SiC-Si3N4-Si2N2O 复合粉末的合成特点,以及用这种粉末生产的热压陶瓷的结构和性能。合成 SiC-Si3N4-Si2N2O 粉末的最佳成分是通过在空气中将热膨胀石墨(TEG)和硅的 1 : 3 混合物加热到 1200°C 而获得的。在 1200°C 高温下,TEG 与细硅相互作用,在碳化硅中形成碳固溶体,同时释放出热量。产生的热量使 TEG 细胞结构局部体积内的温度升高,空气中的氮气促进了氮化硅、氧氮化硅和无定形相的形成。在一氧化碳、氧化硅和空气氮的参与下形成的各相的最终分布受过程持续时间的影响。合成粉末的微观结构特征是一般的团聚状态,由 Si3N4 和 Si2N2O 的棒状和板状形成。将合成的 SiC-Si3N4-Si2N2O 复合粉末与 Al2O3 和 Y2O3 活化剂进行热压,可获得超细陶瓷,具有更高的硬度和断裂韧性(HV10 = 20.7 GPa 和 KIc = 6.5 MPa - m1/2)。2000°C 烧结的陶瓷与 1850°C 烧结的陶瓷在结构上有所不同,主要是密度和平均晶粒尺寸更大。超细状态极大地影响了陶瓷在干摩擦条件下的耐磨性。在 0.2 兆帕的载荷下,滑动速度为 1 米/秒时,结构元素平均粒度为 0.2 至 1.5 μm 的样品的线性磨损指数为 111 μm/km。这明显低于反应烧结碳化硅(RSSC)工业陶瓷的线性磨损指数(232.4 μm/km)。
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来源期刊
Powder Metallurgy and Metal Ceramics
Powder Metallurgy and Metal Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.90
自引率
20.00%
发文量
43
审稿时长
6-12 weeks
期刊介绍: Powder Metallurgy and Metal Ceramics covers topics of the theory, manufacturing technology, and properties of powder; technology of forming processes; the technology of sintering, heat treatment, and thermo-chemical treatment; properties of sintered materials; and testing methods.
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