Your search keyword '"ATIQ, SHABBAR"' showing total 2 results

1. Enhancement of Curie Temperature ( T) and Magnetization of Fe-Ni Invar alloy Through Cu Substitution and with He Ion Irradiation.

Author

Khan, Sajjad, Ziya, Amer, Ibrahim, Ather, Atiq, Shabbar, Usman, Muhammad, Ahmad, Naseeb, and Shakeel, Muhammad

Subjects

MAGNETIZATION, X-ray diffraction, IRRADIATION, INTERATOMIC distances, LATTICE theory, MAGNETIC moments, SPIN waves

Abstract

The magnetic properties of ternary Fe-Ni-Cu invar alloys are affected by ion irradiation, which goes on increasing with increasing ion fluence (Φ), and by increasing Cu content. In the present study, the ions used are He with 2 MeV energy and with 1 × 10 cm, 1 × 10 cm, 5 × 10 cm, 1 × 10 cm and 5 × 10 cm fluence (dose) for irradiation purpose. The face centered cubic structure of the alloy was investigated after ion irradiation using x-ray diffraction (XRD) and found unchanged. However, the peaks become broader with increasing ion dose. Additionally, the lattice fluctuations were observed in XRD study. Curie temperature ( T) is also increased after irradiation. Many factors are considered here for the reason for increasing T, such as the stopping of incident ions, atomic mixing effect at micro scale level owing to ion irradiation, which might change local concentration and ordering already reported in diffuse scattering, and as a result the Fe-Fe interatomic distance and the Fe-Fe coupling are changed. A comparative study shows that the effect of irradiation on T and magnetization with increasing ion fluence is more distinctive than the addition of Cu. [ABSTRACT FROM AUTHOR]

Published

2016

2. Fracture Resistance of Hybrid Glass Matrix Composite and Its Degradation Due to Thermal Ageing and Thermal Shock.

Author

Dlouhý, Ivo, Chlup, Zdenêk, Atiq, Shabbar, and Boccaccini, Aldo R.

Abstract

In brittle matrix composites reinforced by continuous ceramic fibres, the favourable fracture behaviour is provided by the presence of weak fibre/matrix interfaces, which lead to the fibre pullout effect [1]. The thermal stability and high temperature mechanical properties of silicate matrix composites reinforced by carbon and SiC based fibres in oxidising environments have been investigated quite extensively in the past by conducting thermal aging and thermal cycling experiments over a wide range of temperatures [2–5]. A common result of investigations conducted at temperatures in the range 500–700°C is that there is a decrease of tensile and flexural strength of the composites. It has been shown that this is the consequence of oxidation of the fibres, in case of carbon fibre reinforced composites, or of degradation of the fibre/matrix interphase, which is in fact a carbon-rich nanometric interfacial layer, in SiC fibre reinforced composites [2–5]. [ABSTRACT FROM AUTHOR]

Published

2005