Effects of sulfur vacancies on the crystallographic and spin-rotation transitions of iron sulfide

Baek, Kyung Seon; Park, Kyoung Yong; Kim, Hak Joo; Ok, Hang Nam

doi:10.1103/physrevb.41.9024

Cited by 14 publications

(4 citation statements)

References 6 publications

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“…Similar independence of the Morin and a transitions was reported by Thiel and van den Berg [5] using Mössbauer measurements for Fe 0.996 S, though they found that T M was lower by 28 K than T a in contrast to the other results [6][7][8].…”

supporting

confidence: 85%

Mo¨ssbauer study of iron sulfides doped with 3d-transition metals

Nam¹,

Kim²,

Han³

2005

Solid State Communications

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supporting

confidence: 85%

Mo¨ssbauer study of iron sulfides doped with 3d-transition metals

Nam¹,

Kim²,

Han³

2005

Solid State Communications

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“…g 0 and g 1 represent the absolute values of g factors for the ground and the first excited levels of the 57 Fe nucleus, respectively. μN stands for the nuclear magneton and H is the magnetic hyperfine field [5]. Therefore, from Eq.…”

Section: Resultsmentioning

confidence: 99%

“…1 [5]. The quartz tube with two narrow necks was first filled with the desired amount of sulfur and then covered by one layer of titanium and iron powder each.…”

Section: Methodsmentioning

confidence: 99%

Effects of Titanium Impurity on the Crystallographic and Spin-rotation Transitions of FeS

Nam¹,

Kim²

2011

Journal of Magnetics

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The effects of titanium ions on the crystallographic and spin-rotation transitions in iron sulfide have been examined by Mössbauer spectroscopy in the temperature range of 78 to 600 K. It is noted that the titanium impurity of Ti 0.02 Fe 0.98 S affects both the crystallographic and spin-rotation transitions of the iron sulfide. 2% impurity of Ti 2+ in FeS causes the increase in the difference between the spin rotation and α transition temperature by as much as 10 K compared with that for FeS. Both 1c and 2c structures coexist in the range between the α transition temperature and approximately 26 K, with a smaller hyperfine field corresponding to the 1c structure. The spin-rotation temperature for Ti 0.02 Fe 0.98 S was measured to be 365 K, which is 10 K lower than the α transition temperature. By the 2% impurity of Ti 2+ in FeS the Néel temperature appreciably is not affected.

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“…On heating, the Low Temperature Phase (LTP), the superstructure (P62c) derived from the NiAs-type structure, transforms at around 400 K into the High Temperature Phase (HTP), a transitional phase which can be described by the MnP (Pnma) orthorhombic structure [2][3][4]. The transition is reversible and of the first order, then both phases coexist within a temperature interval which, depending on stoichiometry, goes from a few degrees to around 200 K. Both phases are antiferromagnetic with iron atoms located at unique crystallographic sites.…”

Section: Introductionmentioning

confidence: 99%

A quasi-continuous observation of the α-transition of Fe1 + x S by Mössbauer line tracking

et al. 2009

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Mössbauer absorption line tracking methodology, under a constant velocity strategy, is used for a quasi-continuous observation of the α-transition on slightly non stoichiometric Fe 1+x S alloy. To this end, two strategies were applied: an intelligent absorption line tracking with a control algorithm that uses the data measured in the previous region to establish the position of the next partial spectral range; and a predetermined line tracking in which temperature evolution of a partial spectral region of interest (ROI) is programmed. The latter uses results from the former, in order to achieve a quasi-continuous partial spectral observation. These experiments clearly demonstrate that line tracking allows a more efficient use of the radioactive source, as the effort is concentrated in a partial region of the spectra from which the desired information can be obtained.

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Effects of sulfur vacancies on the crystallographic and spin-rotation transitions of iron sulfide

Cited by 14 publications

References 6 publications

Mo¨ssbauer study of iron sulfides doped with 3d-transition metals

Mo¨ssbauer study of iron sulfides doped with 3d-transition metals

Effects of Titanium Impurity on the Crystallographic and Spin-rotation Transitions of FeS

A quasi-continuous observation of the α-transition of Fe1 + x S by Mössbauer line tracking

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