Hyperfine interactions in Tb0.27Dy0.73(Fe1–xCox)2 compounds at 77 K

Bodnar, W.; Szklarska-Łukasik, M.; Stoch, P.; Zachariasz, P.; Pszczoła, J.; Suwalski, J.

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Tytuł artykułu

Hyperfine interactions in Tb0.27Dy0.73(Fe1–xCox)2 compounds at 77 K

Autorzy

Bodnar W. , Szklarska-Łukasik M. , Stoch P. , Zachariasz P. , Pszczoła J. , Suwalski J.

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Abstrakty

The synthesis of materials, crystal structure and 57Fe Mössbauer effect studies at 77 K were performed for intermetallics Tb0.27Dy0.73(Fe1–xCox)2. The starting compound Tb0.27Dy0.73Fe2 of this Fe/Co substituted series is known as Terfenol-D. XRD measurements evidence a pure cubic Laves phase C15, MgCu2-type. The determined unit cell parameter decreases across the series. Co substitution introduces a local area, in the subnanoscale, with random Fe/Co neighbourhoods of the 57Fe atoms. Mössbauer effect spectra for the Tb0.27Dy0.73(Fe1–xCox)2 series collected at 77 K consist of a number of locally originated subspectra due to random composition of Fe and Co atoms in the nearest neighbourhood. Hyperfine interaction parameters: isomer shift, magnetic hyperfine field and a quadrupole interaction parameter were obtained from the fitting procedure of the spectra, both for the local area and for the sample as bulk. As a result of Fe/Co substitution, a Slater-Pauling type curve for the average magnetic hyperfine field vs. Co content in the Tb0.27Dy0.73(Fe1–xCox)2 series is observed. It is found that the magnetic hyperfine fields corresponding to the local area sorted out against Co contribution in the Fe/Co neighbourhoods also create a dependence similar to the Slater-Pauling type curve.

Słowa kluczowe

intermetallics crystal structure Laves phase Mössbauer effect hyperfine interaction Slater-Pauling dependence

Wydawca

Institute of Nuclear Chemistry and Technology

Czasopismo

Nukleonika

Rocznik

2009

Tom

Vol. 54, No. 4

Strony

227--232

Opis fizyczny

Bibliogr. 32 poz., rys.

Twórcy

autor

Bodnar W.

autor

Szklarska-Łukasik M.

autor

Stoch P.

autor

Zachariasz P.

autor

Pszczoła J.

autor

Suwalski J.

Faculty of Physics and Applied Computer Science, AGH University of Science and Technology, 30 A. Mickiewicza Ave., 30-059 Kraków, Poland, Tel.: +48 12 617 2990, Fax: +48 12 634 0010, pszczola@agh.edu.pl

Bibliografia

1. Barbara B, Gignoux D, Vettier C (1988) Lectures on modern magnetism. Science Press Beijing, Berlin Heidelberg
2. Burzo E, Chełkowski A, Kirchmayr HR, Madelung O, Wijn HPJ (eds) (1990) Landolt-Börnstein numerical data and functional relationships in science and technology. New Series, Group III. Vol. 19, subvol. d2. Springer, Berlin
3. Burzo E, Kirchmayr HR, Gschneidner KA Jr, Eyring L (eds) (1989) Handbook on the physics and chemistry of rare earths. Vol. 12. North-Holland Publ. Co, Amsterdam
4. Buschow KHJ (1980) Rare earth compounds. In: Wohlfarth EP (ed) (1980) Ferromagnetic materials. Vol. 1.North-Holland Publ. Co, Amsterdam, pp 297–414
5. Campbell IA (1972) Indirect exchange for rare earths in metals. J Phys F: Met Phys 2:L47–L50
6. Clark AE (1980) Magnetostrictive rare earth-Fe2 compounds. In: Wohlfarth ER (ed) Ferromagnetic materials. Vol. 1. North-Holland Publ. Co, Amsterdam, pp 531–589
7. Cullen JR, Clark AE (1977) Magnetostriction and structural distortion in rare-earth intermetallics. Phys Rev B 15:4510–4515
8. Dhilsha KR, Rama Rao KVS (1993) Investigation of magnetic, magnetomechanical, and electrical properties of the Tb0.27Dy0.73Fe2–xCox system. J Appl Phys 73:1380–1385
9. Feller W (1961) An introduction to probability theory and its applications, 2nd ed. Vol. 1. Wiley, London, pp 175–189
10. Fiebig M (2005) Revival of the magnetoelectric effect. J Phys D: Appl Phys 38:R123–R152
11. Gicala B, Pszczoła J, Kucharski Z, Suwalski J (1994) Two Slater-Pauling dependences for Dy-3d metal compounds. Phys Lett A 185:491–494
12. Gicala B, Pszczoła J, Kucharski Z, Suwalski J (1995) Magnetic hyperfine fields of Dyx(Fe-Co)y compounds. Solid State Commun 96:511–515
13. Gu K, Li J, Ao W, Jian Y, Tang J (2007) The magnetocaloric effect in (Dy,Tb)Co2 alloys. J Alloys Compd 441:39–42
14. Guo ZJ, Zhang ZD, Wang BW, Zhao XG, Geng DY, Li W (2001) Anisotropy compensation and spin reorientation in Tb1–xDyx(Fe0.8Co0.2)2. J Phys D: Appl Phys 34:884–888
15. Ilyushin AS, Nikitin SA, Ngiep NV, Opalenko AA, Tereshina IS, Firov AI (2007) X-ray and Mössbauer studies of the Tb0.3Dy0.7Fe2–xCox system alloys. Mosc Univ Phys Bull 62:237–239
16. Kishore S, Markandeyulu G, Rama Rao KVS, Das TP (1997) 57Fe Mössbauer investigations on the hydrogenated compounds of Dy0.73Tb0.27Fe1.5Co0.5. Solid State Comm 104:735–740
17. Laves F (1939) Kristallographie der Legierungen. Naturwissenschaften 27:65–73
18. Nan CW, Bichurin MI, Dong S, Viehland D, Srinivasan G (2008) Multiferroic magnetoelectric composites: historical perspective, status, and future directions. J Appl Phys 103:031101
19. Nan CW, Liu G, Lin Y (2003) Influence of interfacial bonding on giant magnetoelectric response of multiferroic laminated composites of Tb1–xDyxFe2 and PbZrxTi1–xO3. Appl Phys Lett 83:4366–4368
20. Politova GA, Tereshina IS, Nikitin SA et al. (2005) Effect of hydrogenation on the magnetic and magnetoelastic properties of the Tb0.27Dy0.73Fe2 and Tb0.27Dy0.73Co2 compounds with compensated magnetic anisotropy. Phys Solid State 47:1909–1913
21. Rietveld HM (1969) A profile refinement method for nuclear and magnetic structures. J Appl Cryst 2:65–71
22. Rodriguez-Carvajal J (1993) Recent advances in magnetic structure determination by neutron powder diffraction. Physica B 192:55–69
23. Segnan R, Deriu A (1992) Hyperfine fields studies in Laves phase intermetallic compounds. J Magn Magn Mater 104/107:1399–1400
24. Senthil Kumar M, Reddy KV, Rama Rao KVS, Das TP (1995) 57Fe Mössbauer investigations on the Dy0.73Tb0.27Fe2–xNix and Ho0.85Tb0.15Fe2-yNiy systems. Phys Rev B 52:6542–6549
25. Stoch P, Onak M, Pańta A, Pszczoła J, Suwalski J (2002) Synthesis and crystal structure of Dy(Fe-Co-Al)2. IEA Monographs. Vol. 5. Instytut Energii Atomowej, Otwock- -Świerk (in Polish)
26. Stoch P, Pszczoła J, Guzdek P, Chmist J, Pańta A (2005) Electrical resistivity studies of Dy(Fe1–xCox)2 compounds. J Alloys Compd 394:116–121
27. Table of periodic properties of the elements (1980) Sargent-Welch Scientific Company, Skokie
28. Taylor KNR (1971) Intermetallic rare-earth compounds. Adv Phys 20:551–660
29. Wertheim GK (1964) Mössbauer effect: principles and applications. Academic Press, New York, pp 59–71 232 W. Bodnar et al.
30. Westwood P, Abell JS, Clarke IH, Pitman KC (1988) Microstructure and magnetostriction in rare-earth-iron alloys. J Appl Phys 64:5414–5416
31. Zhang N, Fan J, Rong X, Cao H, Wei J (2007) Magnetoelectric effect in laminate composites of Tb1–xDyxFe2–y and Fe-doped BaTiO3. J Appl Phys 101:063907
32. Zheng X, Zhang P, Fan D, Li F, Hao Y (2005) A structural, magnetostrictive and Mössbauer study of Tb0.3Dy0.7(Fe0.9T0.1)1.95 alloys. Science in China Ser G 48:750–756

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