2000
DOI: 10.1080/13642810008208614
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Fe spin structure in Tb/Fe multilayers

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Cited by 12 publications
(12 citation statements)
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References 39 publications
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“…The high perpendicular remanence indicates that nearly a single-domain state exists at H = 0 Oe. Our finding of perpendicular magnetic anisotropy in Tb/bcc-Fe multilayers is in agreement with earlier reports [7][8][9]. However, our observation of a high perpendicular remanence at RT in such multilayers is a new result.…”
Section: Experimental Procedures and Sample Characterizationsupporting
confidence: 94%
See 1 more Smart Citation
“…The high perpendicular remanence indicates that nearly a single-domain state exists at H = 0 Oe. Our finding of perpendicular magnetic anisotropy in Tb/bcc-Fe multilayers is in agreement with earlier reports [7][8][9]. However, our observation of a high perpendicular remanence at RT in such multilayers is a new result.…”
Section: Experimental Procedures and Sample Characterizationsupporting
confidence: 94%
“…5 shows the CEMS spectra (measured at RT (a) and 80 K (b)) of the Fe/Tb multilayer on GaAs(001)-LED, which includes the 5 ML thick 57 Fe tracer layer in the center of the first 2.6 nm thick (epitaxial) Fe(001) film on the GaAs surface. In agreement with literature reports [7][8][9], these spectra could be least-squares fitted with two spectral components. Subspectrum (1) is a dominant Zeeman-split sextet with relatively sharp lines originating from 57 Fe atoms in bulk-like bcc-Fe local surroundings; it was fitted with a narrow Gaussian distribution of hyperfine magnetic fields, P(B hf ).…”
Section: Experimental Procedures and Sample Characterizationsupporting
confidence: 78%
“…The PMA is conceived to be caused by antiferromagnetically exchange-coupled Fe-Tb atomic pairs combined with singleion anisotropy and the large orbital moment of the Tb ion [123][124][125]. An ultrathin amorphous Fe-Tb alloy phase at the Fe/Tb interface (a few atomic layers thick), as observed by Mössbauer spectroscopy [116][117][118][119][120][121], is also involved in creating PMA. Figure 19 shows CEM spectra taken at RT (top) and 80 K (bottom) from a GaAs(001)-based LED (with an InGaAs quantum well) carrying a Tb/Fe-multilayer electrode and a 5-ML-thick 57 Fe(001) probe layer at the interface .…”
Section: Ferromagnet/semiconductor Heterostructures: Fe On Gaas(001)mentioning
confidence: 99%
“…[109,110]. It is well known that bcc-Fe layers in nanoscale Fe/Tb multilayers exibit PMA [26,[116][117][118][119][120][121][122][123][124][125] due to interface anisotropy. The PMA is conceived to be caused by antiferromagnetically exchange-coupled Fe-Tb atomic pairs combined with singleion anisotropy and the large orbital moment of the Tb ion [123][124][125].…”
Section: Ferromagnet/semiconductor Heterostructures: Fe On Gaas(001)mentioning
confidence: 99%
“…The PMA induced by the antiferromagnetically coupled Fe/Tb interfaces competes with the magnetic dipolar interaction ('shape anisotropy') [3][4][5], which orients the magnetization of most conventional ferromagnetic thin films into the film plane. An integration of ferromagnetic materials with PMA and semiconductors in hybrid systems opens promising perspectives for novel devices, e.g., in the field of semiconductor (SC) based spin electronics.…”
mentioning
confidence: 99%