Paper Titles

Electroless Sn Deposition on Magnesium Alloy and Wastewater Treatment
p.119

Conformal Geometry Solitons
p.123

Effect of Passivation on Pitting Corrosion of 316L Stainless Steel in Concentrated Seawater
p.127

Milling Parameter Optimization Based on Control of Aluminum Alloy 7475 Surface Roughness
p.132

A Novel Electrodeposited Ni-Cr-Al Nanocomposite with Improved Oxidation Resistance
p.137

Comparison of Hot Corrosion Resistance of YSZ and CYSZ Thermal Barrier Coatings in Presence of Sulfate-Vanadate Molten Salts
p.141

Multi-Level Recommendation for Sketch Based 3D Toy Modeling
p.145

Effects on Corrosion Resistance of Ce-Sealed Ni-P Coatings with Ni-Low P and Ni-Medium P
p.151

Preparation and Photocatalytic Activity of Ag-TiO₂/CNT Photocatalyst
p.157

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 472-475A Novel Electrodeposited Ni-Cr-Al Nanocomposite...

A Novel Electrodeposited Ni-Cr-Al Nanocomposite with Improved Oxidation Resistance

Article Preview

Abstract:

A novel Ni-3Cr-10Al nanocomposite (wt.% ) was fabricated by co-electrodeposition of Ni matrix with Cr and Al nanoparticles. Oxidation in air at 900 oC showed that the Ni-3Cr-10Al nanocomposite compared with the alloy showed good oxidation behavior due to the selective oxidation of Al favored by its unique structure.

You might also be interested in these eBooks

Advanced Manufacturing Technology, ICMSE 2012

Info:

Periodical:

Advanced Materials Research (Volumes 472-475)

Pages:

137-140

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.472-475.137

Citation:

Cite this paper

Online since:

February 2012

Authors:

Xiu Ying Yang, Xiao Peng, Fu Hui Wang

Keywords:

Electro-Deposition, Nanocomposite, Ni-Cr-Al, Oxidation

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2012 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] Goward GW, Boone DH, Ginnins CS. Trans ASM 1967;60:228.

[2] Goward GW, Boone DH. Oxid Met 1971;3:475.

[3] Gupta BK, Seigle LL. Thin Solid Films 1980;73:365.

[4] Nicholls JR, Hancock P, Al-Yasiri L H. Mater Sci Technol 1989;5:799.

[5] Wang F, Lou H. Mater Sci Eng 1990;129A: 279.

[6] Liu Y, Traugott E, Fischer A. Surf Coat Tech 2003;167:68.

[7] Nusair A, Lu J. Surf Coat Tech 2003;166: 37.

[8] Brandl W, Toma D, Kruger J, Matthaus G. Surf Coat Tech 1997; 95:21.

[9] Brandl W, Toma D, Grabke J. Surf Coat Tech1999; 120-121:8.

[10] Foster J, Cameron BP. Carew JA. Trans Inst Met Finish 1985;63: 115.

[11] Honey FJ, Kedward EC, Wride V. J Vac Sci Tech 1986;4A:2593.

[12] Peng X, Zhou Y, Zhang Y, Wang F. Mater Sci Forum 2004;461-464:409.

[13] Zhou Y, Peng X, Wang F. Scripta Mater 2004;50:1429.

[14] Zhang Y, Peng X, Wang F. Mater Lett 2004;58:1134.

[15] Zhou Y, Peng X, Wang F. Oxid Met 2005;64:169.

[16] Zhang C, Peng X, Zhao J, Wang F. J Electrochem Soc 2005;152: B321-B326.

[17] Zhang Y, Peng X, Wang F. Electrchem. Solid St 2005;8:B46.

[18] Wagner C. Z Phys Chem 1933;B21:25.

[19] Smeltzer ww, Haering RR, Kirkaldy JS. Acta Met 1961;9:880.

[20] Perrow JM, Smeltzer WW, Embury JD. Acta Met 1968;16:1209.

[21] Yang X, Peng X, Wang F. Manuscript in preparation.

[22] Liu Zhenyu, G Wei, D KarlL, Wang F. Oxid Met 1998;50:51.

[23] Liu Zhenyu, G Wei, D KarlL, Wang F. Scripta Mater 1997;37:1551.

[24] Kofstad P. High temperature corrosion. London and New York: Elsevier Applied Science; 1988.

[25] Wallwork GR, Hed AZ. Oxid Met 1971;3:171.