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Main Author: Wong, Kin Yip
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.13144
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author Wong, Kin Yip
author_facet Wong, Kin Yip
contents Using Linear Response Theory, with appropriate wave functions and energies from perturbation method, the absorption profiles can be calculated for all three classes of mixed-valence systems as defined by Robin and Day : Class III (delocalized), Class I (localized) and Class II (intermediate between III and I). Based on these absorption profiles, one can calculate the corresponding frequency-dependent optical conductivity profiles with the following results: For all three classes, the optical conductivity profiles are similar to their corresponding absorption profiles in regard to band shape and polarization, except peaks of these profiles tend to shift toward higher frequency with respect to the absorption profiles. The charge transfer absorption (CT band) is the major contributors of optical conductivity. Moreover, the CT-induced IR band, also contributes to optical conductivity, as it borrows its intensity from the CT band and the amount of borrowing depends on its proximity to the latter, as in Class II.
format Preprint
id arxiv_https___arxiv_org_abs_2410_13144
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Dynamic Coupling Model of Optical Conductivity in Mixed-Valence Systems
Wong, Kin Yip
Materials Science
Chemical Physics
Using Linear Response Theory, with appropriate wave functions and energies from perturbation method, the absorption profiles can be calculated for all three classes of mixed-valence systems as defined by Robin and Day : Class III (delocalized), Class I (localized) and Class II (intermediate between III and I). Based on these absorption profiles, one can calculate the corresponding frequency-dependent optical conductivity profiles with the following results: For all three classes, the optical conductivity profiles are similar to their corresponding absorption profiles in regard to band shape and polarization, except peaks of these profiles tend to shift toward higher frequency with respect to the absorption profiles. The charge transfer absorption (CT band) is the major contributors of optical conductivity. Moreover, the CT-induced IR band, also contributes to optical conductivity, as it borrows its intensity from the CT band and the amount of borrowing depends on its proximity to the latter, as in Class II.
title A Dynamic Coupling Model of Optical Conductivity in Mixed-Valence Systems
topic Materials Science
Chemical Physics
url https://arxiv.org/abs/2410.13144