Experimental Study of Lanthanum Boride Ceramic Powder Synthesis Process

Fu Jun Wang; Hui Rong Zhu; Qi Di Xiu; Jing Luo

doi:10.4028/www.scientific.net/AMM.457-458.135

Paper Titles

Study on Preparation and Properties of PMMA Composite Microspheres as the Matrix of Low Density Proppant
p.116

Development and Research of Nanostructured Multi-Layered Composite Coatings for Tool Made of Tungsten-Free Carbides (Cermets)
p.120

Investigation of the Influence of Deep Rolling on the Thermal Fatigue Cracking for AISI H13 Steel
p.127

Microstructure and Properties of SiC Particle Reinforced Aluminum Matrix Composites by Powder Metallurgy Method
p.131

Experimental Study of Lanthanum Boride Ceramic Powder Synthesis Process
p.135

Synthesis, Characterization, and Crystal Structure of Several Novel Acidic Ionic Liquids: 1-ethyl-2-alkyl-benzimidazolium Tetra-Fluoroborate
p.139

Investigation of the Strain Distribution of T-Peel Flexible Polymers Using Digital Image Correlation
p.144

Preparation and Properties of Thermosensitive Poly(N-isopropylacrylamide-co-glycyrrhetinic acid) Microgels for Controlled Growth Factor Release
p.148

On the Performance of 17Ni/(10NiO-NiFe₂O₄) Cermet by Hot-Press Sintering Technology: Sintering Temperature Effects
p.152

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 457-458Experimental Study of Lanthanum Boride Ceramic...

Experimental Study of Lanthanum Boride Ceramic Powder Synthesis Process

Abstract:

In this paper, the physical and chemical properties of LaB₆ Ceramics are introduced, the influence of fabrication techniques on the microstructure and properties of LaB₆ Ceramics are discussed. The combustion synthesis process was considered as the proper method for fabrication of LaB₆ Ceramic powder with high purity. The results showed that the control additive has a great influence on the synthesis processand the nanoLaB₆ Ceramic powder with high purity can be produced made when the content of the control additive is 30%.

You might also be interested in these eBooks

Frontiers of Mechanical Engineering and Materials Engineering II

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 457-458)

Pages:

135-138

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.457-458.135

Citation:

Cite this paper

Online since:

October 2013

Authors:

Fu Jun Wang, Hui Rong Zhu, Qi Di Xiu, Jing Luo

Keywords:

Ceramic, Fabrication Techniques, High Purity

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Zheng shuqi, Min Guanghui, Yu Huashum, et al: Aeronautical Manufacturing Technology. Vol. 3 (2000), pp.50-55.

Google Scholar

[2] Monnier R, Delley B: Physical Review B. Vol. 3 (2004), pp.193-403.

Google Scholar

[3] Waldhauser W, Mitterer C, Laimer J, et al: Surface and Coatings Technology. Vol. 9 (1995) , pp.74-75.

Google Scholar

[4] Mitterer C, Komenda-Stallmaier J: Surface and Coatings Technology. Vol. 3 (1995), pp.74-78.

Google Scholar

[5] Poderno V, Poderno Y B: Less-Common Met. Vol. 8 (1979), pp.43-48.

Google Scholar

[6] Jiro Shiokawa, Qu Yuzhong, Yu Zhonghou. Yu Zhonghou. The Latest ApplicationTechnology of Rare Earth, Beijing Chemical Industry Press, Beijing, (1993).

Google Scholar

[7] Zhang Cuiwei: Opto-electronic Technology. Vol. 2 (1989), pp.23-25.

Google Scholar

[8] He Chengdan, Li Heqi, LI Chunxu, et al: Journal of Lanzhou University of Technology. Vol. 4 (2004) , pp.47-49.

Google Scholar

[9] Zheng Shuqi, Min Guanghui, Zou Zengda, et al: Journal of Ceramics. Vol. 4 (1991), pp.306-312.

Google Scholar

[10] Dou Zhihe, Zhang Ting-an, Wang Yanli, et al: Journal of Northeastern University. Vol. 3 (2005) , pp.67-69.

Google Scholar

[11] Wang Weimin, Fu Zhengyi, Yuan Runzhang, et al: Journal of Materials Processing Technology. Vol. 2 (1998), pp.162-168.

Google Scholar

[12] Su Yuchang, Xiao Lihua, Fu Yunchang, et al: Scientia Sinica G: Physics; Mechanics & Astronomy. Vol. 1(2011) , pp.44-46.

Google Scholar

[13] Zhou Shenlin, Liu Danmin, Zhang Jiuxin, el al. Rare Metal Materials and Engineering. Vol. 2( 2009) , pp.11-14.

Google Scholar

[14] Zhang Tingan, Dou Zhihe: Journal of Inorganic Materials. Vol. 3( 2006) , pp.34-37.

Google Scholar

[15] Shi Qingxuan, Lin Zulun, LI Jianjun, et al: Chinese Journal of Electron Devices. Vol. 3( 2007) , pp.23-26.

Google Scholar

[16] Song Ye, Yi Donghou , Ren Yizhu , et al: Journal of Materials Science & Technology. Vol. 2( 2011), pp.27-30.

Google Scholar