Fe-Silicides Formed with Molecular Beam Epitaxy and Studied with Conversion Electron Mössbauer Spectroscopy

Degroote, Stefan; Langelaar, M.H.; Kobayashi, Takaaki; Dekoster, J; Wächter, J. De; Moons, R; Niesen, L.; Langouche, Guido

doi:10.1557/proc-320-133

Cited by 9 publications

(11 citation statements)

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“…However, Fe defective non-stoichiometric Fe 1Àx Si, or strain at the interface, give rise to a distribution of locally noncubic site symmetry, which is reflected in CEMS spectra as a doublet of large linewidth. 11,29 In the present spectra, the fitted doublets show quadrupolar splittings ranging from QS ¼ 0.65(2) to 0.67(1) mm/s, isomer shifts from d ¼ 0.223(3) to 0.25(1) mm/s (with respect to a-Fe) and large linewidths LW ¼ 0.55(1) to 0.62(3) mm/s. This is consistent with the defective/strained paramagnetic c-Fe 1Àx Si phase.…”

Section: B Compositional Study By Cemsmentioning

confidence: 51%

“…According to previous works on the Fe-Si interfaces, 3,5,11,12,15,[27][28][29][30][31] these compounds would have a magnetic Fe 1Àx Si x alloy, and a paramagnetic silicide. The non-stoichiometric c-Fe 1Àx Si phase (0 x 0.5) has been proposed as that paramagnetic compound.…”

Section: B Compositional Study By Cemsmentioning

confidence: 96%

“…The non-stoichiometric c-Fe 1Àx Si phase (0 x 0.5) has been proposed as that paramagnetic compound. 11,27,29,30,[32][33][34][35] We focus our attention on the analysis of the paramagnetic component given by the doublets. The c-FeSi phase with the cubic CsCl structure should show a singlet.…”

Section: B Compositional Study By Cemsmentioning

confidence: 99%

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Iron silicide formation at different layers of (Fe/Si)3 multilayered structures determined by conversion electron Mössbauer spectroscopy

Badía-Romano

Rubín

Magén

et al. 2014

Journal of Applied Physics

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The morphology and the quantitative composition of the Fe-Si interface layer forming at each Fe layer of a (Fe/Si)3 multilayer have been determined by means of conversion electron Mössbauer spectroscopy (CEMS) and high-resolution transmission electron microscopy (HRTEM). For the CEMS measurements, each layer was selected by depositing the Mössbauer active 57Fe isotope with 95% enrichment. Samples with Fe layers of nominal thickness dFe = 2.6 nm and Si spacers of dSi = 1.5 nm were prepared by thermal evaporation onto a GaAs(001) substrate with an intermediate Ag(001) buffer layer. HRTEM images showed that Si layers grow amorphous and the epitaxial growth of the Fe is good only for the first deposited layer. The CEMS spectra show that at all Fe/Si and Si/Fe interfaces a paramagnetic c-Fe1−xSi phase is formed, which contains 16% of the nominal Fe deposited in the Fe layer. The bottom Fe layer, which is in contact with the Ag buffer, also contains α-Fe and an Fe1−xSix alloy that cannot be attributed to a single phase. In contrast, the other two layers only comprise an Fe1−xSix alloy with a Si concentration of ≃0.15, but no α-Fe.

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Section: B Compositional Study By Cemsmentioning

confidence: 51%

Section: B Compositional Study By Cemsmentioning

confidence: 96%

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Iron silicide formation at different layers of (Fe/Si)3 multilayered structures determined by conversion electron Mössbauer spectroscopy

Badía-Romano

Rubín

Magén

et al. 2014

Journal of Applied Physics

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show abstract

“…This fitted density is similar to that of the stable stoichiometric -FeSi phase (q ¼ 5:19 g/cm 3 [29]), but it also lies between the value 4.73 g/cm 3 of the highly Fe-defective and epitaxially stabilized c-Fe 0.5 Si [30] and the close to stoichiometric c-Fe 0.88 Si [31], both with the CsCl structure. c-Fe 1Àx Si has been claimed to appear in the Fe/Si interface [18,19,12,15]. The fitted thickness has to be compared to a previous determination by GIXRR [14], where the Si-on-Fe interface showed also a thickness of 1.4 nm and the fitted optical constant turned out to be that of FeSi.…”

Section: Reflectivity Measurementsmentioning

confidence: 96%

“…Different silicide phases like FeSi [16,17,14], c-Fe 1Àx Si [18,19,12], FeSi 2 [20,17,15] and Fe 3 Si [11,21,22] have been proposed to be formed at the Fe-on-Si interface. In contrast, in the Si-on-Fe interface some authors report only the presence of the paramagnetic c-Fe 1Àx Si (0 6 x 6 0:5) [11,19,12,23], while others state that a ferromagnetic Fe rich Fe(Si) solid solution is also present [18,15,24]. The contradictions may be caused by differences in the samples used; specifically, the substrate and the number and thickness of the Si and Fe layers.…”

Section: Introductionmentioning

confidence: 99%