Reaction behavior of trace oxygen during combustion of falling FeSi75 powder in a nitrogen flow

Bin Li; Jun-hong Chen; Peng Jiang; Ming-wei Yan; Jia-lin Sun; Yong Li

doi:10.1007/s12613-016-1312-2

International Journal of Minerals, Metallurgy, and Materials ›› 2016, Vol. 23 ›› Issue (8) : 959 -965. DOI: 10.1007/s12613-016-1312-2

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Reaction behavior of trace oxygen during combustion of falling FeSi75 powder in a nitrogen flow

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Abstract

To explore the reaction behavior of trace oxygen during the flash combustion process of falling FeSi75 powder in a nitrogen flow, a flash-combustion-synthesized Fe-Si₃N₄ sample was heat-treated to remove SiO₂. The samples before and after the treatment were investigated by X-ray diffraction, scanning electron microscopy, and transmission electron microscopy, and the formation mechanism of SiO₂ was investigated. The results show that SiO₂ in the Fe-Si₃N₄ is mainly located on the surface or around the Si3N4 particles in dense areas, existing in both crystalline and amorphous states; when the FeSi75 particles, which are less than 0.074 mm in size, fell in up-flowing hot N₂ stream, trace oxygen in the N₂ stream did not significantly hinder the nitridation of FeSi75 particles as it was consumed by the surface oxidation of the generated Si₃N₄ particles to form SiO₂. At the reaction zone, the oxidation of Si₃N₄ particles decreased the oxygen partial pressure in the N₂ stream and greatly reduced the opportunity for FeSi75 particles to be oxidized into SiO₂; by virtue of the SiO₂ film developed on the surface, the Si₃N₄ particles adhered to each other and formed dense areas in the material.

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silicon nitride / combustion synthesis / oxygen / atmosphere

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Bin Li, Jun-hong Chen, Peng Jiang, Ming-wei Yan, Jia-lin Sun, Yong Li. Reaction behavior of trace oxygen during combustion of falling FeSi75 powder in a nitrogen flow. International Journal of Minerals, Metallurgy, and Materials, 2016, 23(8): 959-965 DOI:10.1007/s12613-016-1312-2

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References

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[1]	Chen J. H., Wang X. D., Sun J. L., Zhan H. S., Song W. Research on the Fe-silicon nitride material self-producing N2 at high temperature. J. Univ. Sci. Technol. Beijing, 2006, 13(1): 78.

[2]	Wang H. B., Han J. C., Du S. Y. Effect of nitrogen pressure and oxygen-containing impurities on self-propagating high temperature synthesis of Si3N4. J. Eur. Ceram. Soc., 2001, 21(3): 297.

[3]	Ziatdinov M. K., Shatokhin I. M. Self-propagating high-temperature synthesis of ferrosilicon nitride. Steel Transl., 2008, 38(1): 39.

[4]	Chen K., Huang Z. H., Liu Y. G., Fang M. H., Huang J. T., Xu Y. G. Synthesis of ß-Si3N4 powder from quartz via carbothermal reduction nitridation. Powder Technol., 2013, 235, 728.

[5]	Chen D. Y., Zhang B. L., Zhuang H. R., Li W. L., Xu S. Y. Preparation and growth mechanism of ß-Si3N4 rod-like crystals by combustion synthesis. Mater. Lett., 2002, 57(2): 399.

[6]	Chukhlomina L. N., Maksimov Y. M. Effect of the silicon content in the initial alloy on synthesis of silicon nitride in burning ferrosilicon in nitrogen. Glass Ceram., 2008, 65(3): 125.

[7]	Kometani K., Iizuka K., Kaga T. Behavior of ferro-Si3N4 in taphole mud of blast furnace. Taikabutsu, 1998, 50(6): 326.

[8]	Lopes A. B. Influence of ferro silicon nitride on the performance of the modern taphole mud for blast furnace. Refract. Appl. News, 2002, 7(5): 26.

[9]	Ohno H., Kaga T., Takata M. The reaction of ferro-sillicon nitride in carbon refractory. Taikabutsu, 2002, 54(11): 574.

[10]	Heikinheimoa E., Isomäkia I., Kodentsovb A. A., van Loo F. J. J. Chemical interaction between Fe and silicon nitride ceramic. J. Eur. Ceram. Soc., 1997, 17(1): 25.

[11]	Zhang Y., Peng D., Wen H. Sintering process of special ceramics Fe-Si₃N₄ bonded SiC. J. Iron Steel Res., 2002, 14(6): 25.

[12]	Chen J. H. The Composition and Structure of Fe-Si₃N₄ and its Effect on High Temperature Performance of Al₂O₃-SiC-C Composite Refractories, 2006, Beijing, University of Science and Technology Beijing, 16.

[13]	Lee W. C., Chung S. L. Combustion synthesis of Si3N4 powder. J. Mater. Res., 1997, 12(3): 805.

[14]	Li J. F., Li K., Li G. B., Yan D. M. Preparation of Si3N4 powder by combustion synthesis. J. Ceram. Process. Res., 2009, 10(3): 296.

[15]	Yin S. W., Wang L., Tong L. G., Yang F. M., Li Y. H. Kinetic study on the direct nitridation of silicon powders diluted with —Si₃N₄ at normal pressure. Int. J. Miner. Metall. Mater., 2013, 20(5): 493.

[16]	Chen J. H., Song W., Liu X. G., Sun J. L. Formation mechanism of FexSi particles in ferro-silicon nitride prepared via flashing combustion. J. Univ. Sci. Technol. Beijing., 2009, 31(5): 597.

[17]	Cao H. J., Liang X. L. Determination of SiO₂ content in SiC products bonded by Si3N4. Refractories, 2007, 41(3): 236.

[18]	Peuckert M., Greil P. Oxygen distribution in silicon nitride powders. J. Mater. Sci., 1987, 22(10): 3717.

[19]	Castanhoa S. M., Fierrob J. L. G., Morenoa R. Surface oxidation of Si₃N₄ green compacts: Effect of sintering aids. J. Eur. Ceram. Soc., 1997, 17(2-3): 383.

[20]	Okada K., Fukuyama K., Kameshima Y. Characterization of surface-oxidized phase in silicon nitride and silicon oxynitride powders by X-ray photoelectron spectroscopy. J. Am. Ceram. Soc., 1995, 78(8): 2021.

[21]	Chen Z. Y. Chemical Thermodynamics of Refractories, 1991, Beijing, Metallurgical Industry Press, 534.

[22]	Li B., Chen J. H., Su J. D., Yan M. W., Sun J. L., Li Y. Morphology of a-Si₃N₄ in Fe–Si₃N₄ prepared via flash combustion. Int. J. Miner. Metall. Mater., 2015, 22(12): 1322.

[23]	Barin I. Thermochemical Data of Pure Substances, 2003 1480.

[24]	Boyer S. M., Moulson A. J. A mechanism for the nitridation of Fe-contaminated silicon. J. Mater. Sci., 1978, 13(8): 1637.

[25]	Ordoñez S., Iturriza I., Castro F. The influence of amount and type of additives on a - ß Si₃N₄ transformation. J. Mater. Sci., 1999, 34, 147.