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The Reconstructive Crystal Structure and the Exchange Energy

Published online by Cambridge University Press:  26 February 2011

Ahmad Yazdani
Affiliation:
[email protected], University, Physics, Jalale Ahmad, Tehran, N/A, Iran
Reza Osati Araghi
Affiliation:
[email protected], Tarbiat Modares University, Tehran, N/A, Iran
Farid Arya
Affiliation:
[email protected], Tarbiat Modares University, Tehran, N/A, Iran
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Abstract

In order to describe the role of temperature variation on suppress of broad range of magnetic transition, the effect of annealing on different samples of a Gd-based intermetallic compound (i.e., Gd2Au) is investigated. The X-ray, AC and D.C susceptibility and electrical resistivity measurements for different annealed samples revealed that: (i) A great exchange dispersion is observed in A.C susceptibility (ii) This unstable exchange can be stabilized at certain annealing temperature, where the short rang unstable Ferromagnetic (F.M) breaks down or even changes to an Antiferromagnetic (AF.M) stable state. (iii) The DC susceptibility shows a spin-glass like transition temperature at TN= 61 K, above which the compound exhibits a completely paramagnetic (P.M) behavior and is field independent. (iv) the iso-termal magnetization does not follow the field induced transition (F.I.T) and behaves completely as a paramagnet which is independent of the field up to the highest available fields. The electrical resistivity measurement shows: a) A pronounced sharp bend at TN=61 K is manifested in ρ(T). b)some strong peak of X-ray pattern change into double adjacent lines in some intervals of low temperatures

Keywords

Type
Research Article
Copyright
Copyright © Materials Research Society 2007

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References

REFERENCES

1. Oesterreicher, H., phys, Stat.sol (a) 39 k91 (1977).Google Scholar
2. Li, X.G., Takahashi, M.Satus, Journal M.M.M 212 145 (2000).Google Scholar
3. Bredimas, H.Gamariseel, Phys.Stat.Sol, (b) 122 (1984).Google Scholar
4. Yakinthos, J.K., et.al, Journal M.M.M 8 (1978) 308.Google Scholar
5. Sill, L.R and Bigger, R.R, J Applied Phys. 46 (3) (1978).Google Scholar
6. Ford, P.J., Contemp.Phys. 23 (1982) 141.Google Scholar
7. O'shea, M.J., Cornelison, S.G., et.al, Solid State Communication 46(1983)313.Google Scholar
8. Yazdani, A. and Gardner, J.St., Phys.Stat.Sol. (b) 209.465 (1998).Google Scholar
9. Harmon, B.N. and Freeman, A.J., Phys.Rev. B 10 (1974) 1979.Google Scholar
10. Masters, O.D.Mc, Schneider, K.A.G, etall, J.Less Common Met. 25 (1971)185.Google Scholar
11. Yazdani, A. and Khorasani, R. Rajaie, J.Sci.Ir, vol.12, No.1 (2001).Google Scholar