Electronic Raman scattering in magnetite: Spin versus charge gap

L. V. Gasparov; A. Rush; G. Güntherodt; H. Berger

doi:10.1103/PhysRevB.79.144303

Electronic Raman scattering in magnetite: Spin versus charge gap

L. V. Gasparov, A. Rush, G. Güntherodt, H. Berger

Research output: Contribution to journal › Article › peer-review

Abstract

We report Raman-scattering data of single crystals of magnetite (Fe3⁢O4) with Verwey transition temperatures (𝑇𝑣) of 123 and 117 K, respectively. Both single crystals reveal broad electronic background extending up to 900 wave numbers (∼110 meV). Redistribution of this background is observed when samples are cooled below 𝑇𝑣. In particular, spectra of the low-temperature phase show diminished background below 300 wave numbers followed by an enhancement of the electronic background between 300 and 400 wave numbers. To enhance the effect of this background redistribution, we divide the spectra just below the transition by the spectra just above the transition. A resultant broad peaklike feature is observed centered at 370±40 wave numbers (45±5 meV). The peak position of this feature does not scale with the transition temperature. We discuss two alternative assignments of this feature to a spin or charge gap in magnetite.

Original language	American English
Article number	144303
Journal	Physical Review B
Volume	79
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevB.79.144303
State	Published - Apr 21 2009

Keywords

Electron spin
Iron oxides
Magnetite
Physics-materials Science
Physics-Strongly Correlated Electrons
Raman spectra
Single crystals
Transition temperature

Disciplines

Atomic, Molecular and Optical Physics
Physics
Quantum Physics
Condensed Matter Physics

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Cite this

@article{10b406672a7f4d949e122d5d0ec9561a,

title = "Electronic Raman scattering in magnetite: Spin versus charge gap",

abstract = "We report Raman-scattering data of single crystals of magnetite (Fe3⁢O4) with Verwey transition temperatures (𝑇𝑣) of 123 and 117 K, respectively. Both single crystals reveal broad electronic background extending up to 900 wave numbers (∼110 meV). Redistribution of this background is observed when samples are cooled below 𝑇𝑣. In particular, spectra of the low-temperature phase show diminished background below 300 wave numbers followed by an enhancement of the electronic background between 300 and 400 wave numbers. To enhance the effect of this background redistribution, we divide the spectra just below the transition by the spectra just above the transition. A resultant broad peaklike feature is observed centered at 370±40 wave numbers (45±5 meV). The peak position of this feature does not scale with the transition temperature. We discuss two alternative assignments of this feature to a spin or charge gap in magnetite.",

keywords = "Electron spin, Iron oxides, Magnetite, Physics-materials Science, Physics-Strongly Correlated Electrons, Raman spectra, Single crystals, Transition temperature",

author = "Gasparov, {L. V.} and A. Rush and G. G{\"u}ntherodt and H. Berger",

note = "Gasparov, L. V., Rush, A., G{\"u}ntherodt, G., & Berger, H. (2009). Electronic Raman scattering in magnetite: Spin versus charge gap. Physical Review. B, Condensed Matter and Materials Physics, 79(14), 144303. https://doi.org/10.1103/PhysRevB.79.144303",

year = "2009",

month = apr,

day = "21",

doi = "10.1103/PhysRevB.79.144303",

language = "American English",

volume = "79",

journal = "Physical Review B",

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TY - JOUR

T1 - Electronic Raman scattering in magnetite

T2 - Spin versus charge gap

AU - Gasparov, L. V.

AU - Rush, A.

AU - Güntherodt, G.

AU - Berger, H.

N1 - Gasparov, L. V., Rush, A., Güntherodt, G., & Berger, H. (2009). Electronic Raman scattering in magnetite: Spin versus charge gap. Physical Review. B, Condensed Matter and Materials Physics, 79(14), 144303. https://doi.org/10.1103/PhysRevB.79.144303

PY - 2009/4/21

Y1 - 2009/4/21

N2 - We report Raman-scattering data of single crystals of magnetite (Fe3⁢O4) with Verwey transition temperatures (𝑇𝑣) of 123 and 117 K, respectively. Both single crystals reveal broad electronic background extending up to 900 wave numbers (∼110 meV). Redistribution of this background is observed when samples are cooled below 𝑇𝑣. In particular, spectra of the low-temperature phase show diminished background below 300 wave numbers followed by an enhancement of the electronic background between 300 and 400 wave numbers. To enhance the effect of this background redistribution, we divide the spectra just below the transition by the spectra just above the transition. A resultant broad peaklike feature is observed centered at 370±40 wave numbers (45±5 meV). The peak position of this feature does not scale with the transition temperature. We discuss two alternative assignments of this feature to a spin or charge gap in magnetite.

AB - We report Raman-scattering data of single crystals of magnetite (Fe3⁢O4) with Verwey transition temperatures (𝑇𝑣) of 123 and 117 K, respectively. Both single crystals reveal broad electronic background extending up to 900 wave numbers (∼110 meV). Redistribution of this background is observed when samples are cooled below 𝑇𝑣. In particular, spectra of the low-temperature phase show diminished background below 300 wave numbers followed by an enhancement of the electronic background between 300 and 400 wave numbers. To enhance the effect of this background redistribution, we divide the spectra just below the transition by the spectra just above the transition. A resultant broad peaklike feature is observed centered at 370±40 wave numbers (45±5 meV). The peak position of this feature does not scale with the transition temperature. We discuss two alternative assignments of this feature to a spin or charge gap in magnetite.

KW - Electron spin

KW - Iron oxides

KW - Magnetite

KW - Physics-materials Science

KW - Physics-Strongly Correlated Electrons

KW - Raman spectra

KW - Single crystals

KW - Transition temperature

U2 - 10.1103/PhysRevB.79.144303

DO - 10.1103/PhysRevB.79.144303

M3 - Article

SN - 2469-9969

VL - 79

JO - Physical Review B

JF - Physical Review B

IS - 14

M1 - 144303

ER -