Optical spectroscopy of charge-ordering transition

T. Ishikawa; S. Park; T. Katsufuji; T. Arima; Y. Tokura

doi:10.1103/PhysRevB.58.R13326

Optical spectroscopy of charge-ordering transition

T. Ishikawa, S. Park, T. Katsufuji, T. Arima, Y. Tokura

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

72 Citations (Scopus)

Abstract

The change of the electronic structure and lattice dynamics upon the charge-ordering (CO) transition has been investigated for a (Formula presented) crystal by measurements of optical spectra. The CO transition, as characterized by sequential 2:1 ordering of nominal (Formula presented) and (Formula presented) sheets at (Formula presented) activates several additional optical phonon modes due to the charge modulation and opens an optical gap (up to 2Δ∼0.13 eV). The spectral intensity of the activated phonon mode shows a discontinuous increase at (Formula presented) reflecting the first-order nature of the CO transition. By contrast, the optical gap value increases rather continuously with decreasing temperature below (Formula presented) implying the effect of the concomitant antiferromagnetic spin ordering on the gap magnitude and structure.

Original language	English
Pages (from-to)	R13326-R13329
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	58
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevB.58.R13326
Publication status	Published - 1998
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.58.R13326

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title = "Optical spectroscopy of charge-ordering transition",

abstract = "The change of the electronic structure and lattice dynamics upon the charge-ordering (CO) transition has been investigated for a (Formula presented) crystal by measurements of optical spectra. The CO transition, as characterized by sequential 2:1 ordering of nominal (Formula presented) and (Formula presented) sheets at (Formula presented) activates several additional optical phonon modes due to the charge modulation and opens an optical gap (up to 2Δ∼0.13 eV). The spectral intensity of the activated phonon mode shows a discontinuous increase at (Formula presented) reflecting the first-order nature of the CO transition. By contrast, the optical gap value increases rather continuously with decreasing temperature below (Formula presented) implying the effect of the concomitant antiferromagnetic spin ordering on the gap magnitude and structure.",

author = "T. Ishikawa and S. Park and T. Katsufuji and T. Arima and Y. Tokura",

year = "1998",

doi = "10.1103/PhysRevB.58.R13326",

language = "English",

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TY - JOUR

T1 - Optical spectroscopy of charge-ordering transition

AU - Ishikawa, T.

AU - Park, S.

AU - Katsufuji, T.

AU - Arima, T.

AU - Tokura, Y.

PY - 1998

Y1 - 1998

N2 - The change of the electronic structure and lattice dynamics upon the charge-ordering (CO) transition has been investigated for a (Formula presented) crystal by measurements of optical spectra. The CO transition, as characterized by sequential 2:1 ordering of nominal (Formula presented) and (Formula presented) sheets at (Formula presented) activates several additional optical phonon modes due to the charge modulation and opens an optical gap (up to 2Δ∼0.13 eV). The spectral intensity of the activated phonon mode shows a discontinuous increase at (Formula presented) reflecting the first-order nature of the CO transition. By contrast, the optical gap value increases rather continuously with decreasing temperature below (Formula presented) implying the effect of the concomitant antiferromagnetic spin ordering on the gap magnitude and structure.

AB - The change of the electronic structure and lattice dynamics upon the charge-ordering (CO) transition has been investigated for a (Formula presented) crystal by measurements of optical spectra. The CO transition, as characterized by sequential 2:1 ordering of nominal (Formula presented) and (Formula presented) sheets at (Formula presented) activates several additional optical phonon modes due to the charge modulation and opens an optical gap (up to 2Δ∼0.13 eV). The spectral intensity of the activated phonon mode shows a discontinuous increase at (Formula presented) reflecting the first-order nature of the CO transition. By contrast, the optical gap value increases rather continuously with decreasing temperature below (Formula presented) implying the effect of the concomitant antiferromagnetic spin ordering on the gap magnitude and structure.

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Optical spectroscopy of charge-ordering transition

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