Nickelization effect on the high temperature tensile properties of Mg-0.7Y2O3 nanocomposite

S. Fida Hassan; Khin Sandar Tun; F. Patel; Nasser Al-Aqeeli; M. Gupta

doi:10.24425/123819

Nickelization effect on the high temperature tensile properties of Mg-0.7Y₂O₃ nanocomposite

S. Fida Hassan^*
, Khin Sandar Tun
, F. Patel
, Nasser Al-Aqeeli
, M. Gupta

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

In this study, high performance magnesium-yttria nanocomposite's room temperature, strength and ductility were significantly enhanced by the dispersion of nano-sized nickel particles using powder blending and a microwave sintering process. The strengthening effect of the dispersed nano-sized nickel particles was consistent up to 100°C and then it gradually diminished with further increases in the test temperature. The ductility of the magnesium-yttria nanocomposite remained unaffected by the dispersed nano-sized nickel particles up to 100°C. Impressively, it was enhanced at 150°C and above, leading to the possibility of the near net shape fabrication of the nanocomposite at a significantly low temperature.

Original language	English
Pages (from-to)	1411-1415
Number of pages	5
Journal	Archives of Metallurgy and Materials
Volume	63
Issue number	3
DOIs	https://doi.org/10.24425/123819
State	Published - 2018

Bibliographical note

Publisher Copyright:
© 2017 Polish Academy of Sciences.

Keywords

Deformation
High-Temperature
Magnesium
Nanocomposite
Tensile Strength

ASJC Scopus subject areas

Metals and Alloys

Access to Document

10.24425/123819

Cite this

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title = "Nickelization effect on the high temperature tensile properties of Mg-0.7Y2O3 nanocomposite",

abstract = "In this study, high performance magnesium-yttria nanocomposite's room temperature, strength and ductility were significantly enhanced by the dispersion of nano-sized nickel particles using powder blending and a microwave sintering process. The strengthening effect of the dispersed nano-sized nickel particles was consistent up to 100°C and then it gradually diminished with further increases in the test temperature. The ductility of the magnesium-yttria nanocomposite remained unaffected by the dispersed nano-sized nickel particles up to 100°C. Impressively, it was enhanced at 150°C and above, leading to the possibility of the near net shape fabrication of the nanocomposite at a significantly low temperature.",

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author = "Hassan, \{S. Fida\} and Tun, \{Khin Sandar\} and F. Patel and Nasser Al-Aqeeli and M. Gupta",

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AU - Hassan, S. Fida

AU - Tun, Khin Sandar

AU - Patel, F.

AU - Al-Aqeeli, Nasser

AU - Gupta, M.

PY - 2018

Y1 - 2018

N2 - In this study, high performance magnesium-yttria nanocomposite's room temperature, strength and ductility were significantly enhanced by the dispersion of nano-sized nickel particles using powder blending and a microwave sintering process. The strengthening effect of the dispersed nano-sized nickel particles was consistent up to 100°C and then it gradually diminished with further increases in the test temperature. The ductility of the magnesium-yttria nanocomposite remained unaffected by the dispersed nano-sized nickel particles up to 100°C. Impressively, it was enhanced at 150°C and above, leading to the possibility of the near net shape fabrication of the nanocomposite at a significantly low temperature.

AB - In this study, high performance magnesium-yttria nanocomposite's room temperature, strength and ductility were significantly enhanced by the dispersion of nano-sized nickel particles using powder blending and a microwave sintering process. The strengthening effect of the dispersed nano-sized nickel particles was consistent up to 100°C and then it gradually diminished with further increases in the test temperature. The ductility of the magnesium-yttria nanocomposite remained unaffected by the dispersed nano-sized nickel particles up to 100°C. Impressively, it was enhanced at 150°C and above, leading to the possibility of the near net shape fabrication of the nanocomposite at a significantly low temperature.

KW - Deformation

KW - High-Temperature

KW - Magnesium

KW - Nanocomposite

KW - Tensile Strength

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