一维SiAlON的合成及其生长机理<sup>*</sup>

doi:10.11896/j.issn.1005-023X.2017.013.015

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Abstract SiAlON ceramic which possesses excellent mechanical properties at both room temperature and high temperature and good chemical stability is regarded as a kind of important high-temperature structural materials. One-dimensional SiAlON mate-rials (including nanowire, nanorod, nanobelt, etc.) with special monocrystalline structure have potential applications in high-tempe-rature ceramics, optics, electronics and other fields owing to their excellent mechanical properties, unique optical and electrical pro-perties. This paper reviews recent research progress of one-dimensional SiAlON. Meanwhile, the synthesis methods and growth mechanisms of one-dimensional SiAlON are also summarized. Moreover, the future application prospects and developmental direction of one-dimensional SiAlON are proposed.

Key words： SiAlON one-dimensional material growth mechanisms

Published: 10 July 2017 Online: 2018-05-04

CLC number:

TB32

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	Articles by authors
	TIAN Liang
	LIANG Feng
	ZHAO Wanguo
	WANG Junkai
	ZHANG Haijun

Cite this article:

TIAN Liang,LIANG Feng,ZHAO Wanguo, et al. Review on Synthesis Methods and Growth Mechanisms of One-dimensional SiAlON[J]. Materials Reports, 2017, 31(13): 120-125.

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https://www.mater-rep.com/EN/10.11896/j.issn.1005-023X.2017.013.015 OR https://www.mater-rep.com/EN/Y2017/V31/I13/120

1 Izhevskiy V A, Genova L A, Bressiani J C, et al. Progress in Si-AlON ceramics[J]. J Eur Ceram Soc,2000,20(13):2275.
2 Deng X, Li X C, Zhu B Q, et al. In-situ synthesis mechanism of plate-shaped β-Sialon and its effect on Al₂O₃-C refractory properties[J]. Ceram Int,2015,41(10):14376.
3 Lu L L, Zhang S W, Zhang H J, et al. Structures and mechanical properties of Fe- and Cr-incorporated β-Si₅AlON₇: First-principles study[J]. Ceram Int,2016,42(10):11924.
4 Li Z M, et al. Oxidation behavior of β-SiAlON powders fabricated by combustion synthesis[J]. Ceram Int,2016,42:7290.
5 Mark I J, Hideki H, Kiyoshi H, et al. Highly transparent Lu-α-SiAlON[J]. J Am Ceram Soc,2004,87:714.
6 Su X L, Wang P L, Chen W W, et al. Translucent α-SiAlON cera-mics by hot pressing[J]. J Am Ceram Soc,2004,87(4):730.
7 Ali S, Jonson B, et al. Issues associated with the development of transparent oxynitride glasses[J]. Ceram Int,2015,41(3):3345.
8 Krevel J W H, Rutten J W T, Mandal H, et al. Luminescence pro-perties of terbium, cerium, or europium-doped α-SiAlON materials[J]. J Solid State Chem, 2002,165(1):19.
9 Xie R J, Hirosaki N. Silicon-based oxynitride and nitride phosphors for white LEDs—A review[J]. Sci Technol Adv Mater,2007,8:588.
10 Joshi B, Lee S W. Luminescence properties of Eu²⁺, Gd³⁺ and Pr³⁺ doped translucent Sialon phosphors[J]. J Rare Earths,2015,33(11):1142.
11 Yoon C B, Kim S, Choi S W, et al. Highly improved reliability of amber light emitting diode with Ca-alpha-SiAlON phosphor in glass formed by gas pressure sintering for automotive applications[J]. Optics Lett,2016,41(7):1590.
12 Yi X M, Guo R, et al. Spark plasma sintering of combustion-synthesized beta-SiAlON powders[J]. Ceram Int,2016,42(6):6707.
13 Cao G Z, Metselaar R. α-SiAlON ceramics: A review[J]. Chem Mater,1991(2):242.
14 Lindqvist O, Sjöberg J, Hull S, et al. Structural changes in O′-sialons, Si_2-xAl_xN_2-xO_1+x, 0.04≤x≤0.40[J]. Acta Crystallogra-phica Section B,1991,47(5):672.
15 Jamshidi A, Nourbakhsh A A, Naghibi S, et al. Application of the statistical Taguchi method to optimize X-SiAlON and mullite formation in composite powders prepared by the SRN process[J]. Ceram Int,2014,40(1):263.
16 Zhou G H, Li Y W, Li N. Progress of AlN polytypoids[J]. Mater Rev,2004,18(Z1):280(in Chinese).
周国红, 李亚伟, 李楠. AlN多型体研究进展[J]. 材料导报,2004,18(Z1):280.
17 Cheng Z X. Synthesis and characterization of β′-sialon whiskers prepared from the carbothermal reaction of silica fume and α-Al₂O₃[J]. J Mater Sci,1993,28(22):6021.
18 Li X B, Ke C M, Li N. Alumina-carbon refractories strengthened by in-situ synthetic O′-SiAlON whiskers[J]. Refractories,2006,40(6):415(in Chinese).
李喜宝, 柯昌明, 李楠. 原位生成O′-SiAlON晶须增强铝碳耐火材料[J]. 耐火材料,2006,40(6):415.
19 Yue C S, Peng B, Guo M, et al. Study on inducing synthesis and growth mechanism of β-SiAlON whisker[J]. J Synthet Cryst,2011,40(5):287(in Chinese).
岳昌盛, 彭犇, 郭敏, 等. β-SiAlON晶须的诱导合成和生长机制研究[J]. 人工晶体学报,2011,40(5):287.
20 Peng B, Qiu G B, Yue C S, et al. Controllable synthesis of one-dimensional β-SiAlON materials[J]. J Inorgan Mater,2014,29(7):706(in Chinese).
彭犇, 邱桂博, 岳昌盛, 等. 一维β-SiAlON材料可控合成[J]. 无机材料学报, 2014,29(7):706.
21 Alivisatos A P. Semiconductor clusters, nanocrystals, and quantum dots[J]. Science, 1996,271(5251):933.
22 Fan S S, Chapline M G, Franklin N R, et al. Self-oriented regular arrays of carbon nanotubes and their field emission properties[J]. Science,1999,283:512.
23 Niu H L, Chen Q W, Ning M, et al. Synthesis and one-dimensional self-assembly of acicular nickel nanocrystallites under magnetic fields[J]. J Phys Chem B,2004, 108(13):3996.
24 Hou X M, Yu Z Y, Chen Z Y, et al. Single crystalline β-SiAlON nanowhiskers: Preparation and enhanced properties at high temperature[J]. Dalton Trans,2012, 41(23):7127.
25 Dong P, Wang X, Zhang M, et al. The preparation and characte-rization of β-SiAlON nanostructure whiskers[J]. J Nanomater,2008.Doi:10.1155/2008/282187.
26 Hou X M, Yu Z Y, Chou K C, et al. Synthesis of β-SiAlON whis-kers: Dependence of uniform morphology upon preparation conditions[J]. Adv Appl Ceram,2013, 112(3):163.
27 Ng D H L, Cheung T L Y, Kwong F L, et al. Fabrication of single crystalline β′-SiAlON nanowires[J]. Mater Lett,2008,62:1349.
28 Zhang H J, Han B, Liu Z J. Preparation and oxidation of bauxite-based β-Sialon-bonded SiC composite[J]. Mater Res Bull,2006,41(9):1681.
29 Huang J T, Liu Y G, Huang Z H, et al. Ni(NO₃)₂-assisted cataly-tic synthesis and photoluminescence property of ultralong single crystal Sialon nanobelts[J]. Crystal Growth Des,2013,13:10.
30 Huang J T, et al. β-Sialon nanowires, nanobelts and hierarchical nanostructures: Morphology control, growth mechanism and ca-thodoluminescence properties[J]. Nanoscale,2014,6:424.
31 Liu H T, Meng F R, Li Q, et al. Growth mechanism and PL pro-perties of β-Sialon nanobelts/nanowires synthesized in process of aluminothermic reduction nitridation of zircon[J]. CrystEngComm,2015,17(7):1591.
32 Zhang H J, Liu Z J, Zhong X C. Synthesis of O′-SiAlON powder by reduction-nitridation method[J]. J Chinese Ceram Soc,2004,32(10):1189(in Chinese).
张海军, 刘战杰, 钟香崇. 还原氮化法合成O′-SiAlON粉[J]. 硅酸盐学报,2004, 32(10):1189.
33 Liu G H, Chen K X, Zhou H P, et al. Formation of β-SiAlON micropalings consisting of nanorods during combustion synthesis[J]. Scripta Mater,2006,55:935.
34 Liu G H, Chen K X, Zhou H P, et al. Preparation of Ca α-SiAlON powders with rod-like crystals by combustion synthesis[J]. Ceram Int,2006,32:411.
35 Liu G H, Chen K X, Zhou H P, et al. Preparation of Y-SiAlON rod-like crystals and whiskers by combustion synthesis[J]. Mater Lett,2005,59:3955.
36 Zhao H, Wang P Y, Yu J L, et al. An experimental study on synthesis of β-Sialon composites using fly ash and lignite char-preparation and whiskers formation[J]. J Ceram Soc Japan,2015,123(1439):542.
37 Zhang J, Yu J L, Zhao H, et al. Fabrication and analysis of β-Sialon whiskers from fly ash by carbon thermal reduction-nitridation[J]. Appl Mech Mater,2015, 723:610.
38 Zhao H, et al. A mechanistic study on the synthesis of β-Sialon whiskers from coal fly ash[J]. Mater Res Bull,2015,65:47.
39 Yu J K, Ueno S, Hiragushi K, et al. Synthesis of β-SiAlON whis-kers from pyrophyllite[J]. J Ceram Soc Japan,1997,105(9):821.
40 Huang J T, Zhou H P, et al. Preparation and formation mechanism of elongated (Ca,Dy)-α-Sialon powder via carbothermal reduction and nitridation[J]. J Am Ceram Soc,2012,95(6):1871.
41 Qin C L, Wen G W, Wang X Y, et al. Ultra-long Sialon nanobelts: Large-scale synthesis via a pressure enhanced CVD process and photoluminescence characteristics[J]. J Mater Chem,2011,21:5985.
42 Mitomo M, Kuramoto N, Inomata Y. Fabrication of high strength β-Sialon by reaction sintering[J]. J Mater Sci,1979,14:2309.
43 Zhang L, et al. Synthesis of β-SiAlON nano-powder by ammonolysis of alumina-silica gel[J]. J Am Ceram Soc,2014,97(1):40.
44 He E Q, Yue J S, Fan L, et al. Synthesis of single phase β-SiAlON ceramics by reaction-bonded sintering using Si and Al₂O₃ as raw materials[J]. Scripta Mater,2011, 65(2):155.
45 Morsi K. The diversity of combustion synthesis processing: A review[J]. J Mater Sci,2012,47:68.
46 Mazzoni A D, Aglietti E F. Mechanism of the carbonitriding reactions of SiO₂-Al₂O₃ minerals in the Si-Al-O-N system[J]. Appl Clay Sci,1998,12(6):447.
47 Tatli Z, Demir A, Yilmaz R, et al. Effects of processing parameters on the production of β-SiAlON powder from kaolinite[J]. J Eur Ceram Soc,2007,27:743.
48 Tang Y, Yin H F, Yuan H D, et al. Carbothermal reduction nitridation of slag, glass and minerals: Formation process of SiAlON powders with different morphology[J]. Ceram Int,2016,42(6):7499.
49 Dai Z R, Pan Z W, Wang Z L. Novel nanostructures of functional oxides synthesized by thermal evaporation[J]. Adv Funct Mater,2003,13(13):9.
50 Liu G H, et al. Combustion synthesis of SiAlON ceramic powders: A review[J]. Mater Manuf Processes,2013,28(28):113.