Investigation of the bonding mechanism in pyrite using the Mössbauer effect and X-ray crystallography

Finklea, S. L.; Cathey, L.; Amma, E. L.

doi:10.1107/s0567739476001198

Cited by 139 publications

(85 citation statements)

References 16 publications

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“…The computed lattice constant of FeS 2 is 5.415Å in nice agreement with experiment (5.428Å). 33 The calculated band gap is 0.80 eV which is in good agreement with the experimental value of 0.95 eV.…”

Section: Figsupporting

confidence: 83%

DFT Study of Oxidation States on Pyrite Surface Sites

Rozgonyi

Stirling

2015

J. Phys. Chem. C

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Density functional calculations have been performed to study the interaction of oxygen with clean and defective pyrite (100) surfaces. Molecular adsorption states are predicted to undergo dissociation because atomic chemisorption is far more favorable thermodynamically for all surfaces. On the defect-free FeS2 surface molecular adsorption takes place on neighboring iron sites in a side-on fashion. S-adatoms react weakly with O2 whereas S-vacancies bind very strongly molecular oxygen. Dissociative chemisorption on clean surface prefers the sulfur atoms to iron in sharp contrast to water adsorption. Reaction with atomic oxygen is thermodynamically preferred on the defect sites when they are available. Oxidation can fully eliminate the S-adatom sites by SO2 formation. The most favorable sites for oxidation are sulfur vacancies where O atoms can occupy the missing sulfur sites. The predicted oxidation states and their relative stabilities are in agreement with experiments and expected to assist the interpretation of XPS measurements.

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Section: Figsupporting

confidence: 83%

DFT Study of Oxidation States on Pyrite Surface Sites

Rozgonyi

Stirling

2015

J. Phys. Chem. C

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“…Calculations yield a cubic lattice constant of a ¼ 5:410 # A and a S 2 2À bond length of d ¼ 2:194 # A, in agreement with previous calculations [26][27][28] and experiments [29].…”

supporting

confidence: 72%

Highly Spin-Polarized Conducting State at the Interface between Nonmagnetic Band Insulators:LaAlO3/FeS2(001)

Burton

Tsymbal

2011

Phys. Rev. Lett.

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First-principles density functional calculations demonstrate that a spin-polarized two-dimensional conducting state can be realized at the interface between two non-magnetic band insulators. The (001) surface of the diamagnetic insulator FeS 2 (pyrite) supports a localized surface state deriving from Fe dorbitals near the conduction band minimum. The deposition of a few unit cells of the polar perovskite oxide LaAlO 3 leads to electron transfer into these surface bands, thereby creating a conducting interface. The occupation of these narrow bands leads to an exchange splitting between the spin sub-bands, yielding a highly spin-polarized conducting state distinct from the rest of the non-magnetic, insulating bulk. Such an interface presents intriguing possibilities for spintronics applications.

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“…displacements --0.088 (1)A for Fe and 0.096 (1)A, for S with barely significant anisotropy. Finklea, Cathey & Amma (1976) reported 0.056 and 0.062A for these displacements but with no mention of possible extinction effects, which, if uncorrected, tend to reduce them.…”

Section: Structure Of Pyritementioning

confidence: 95%

“…Fe atoms are in sites 4(a) 0,0,0 etc. and S atoms in 8(c) x, x, x etc., x-0.384 (Elliott, 1960) or 0.3851 (Finklea, Cathey & Amma, 1976). Pyrite crystals can be non-stoichiometric and cell dimensions vary slightly.…”

Section: Structure Of Pyritementioning

confidence: 99%