Publication: Theory of Graphene Raman Scattering
Date
2016
Published Version
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Publisher
American Chemical Society (ACS)
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Citation
Heller, Eric J., Yuan Yang, Lucas Kocia, Wei Chen, Shiang Fang, Mario Borunda, and Efthimios Kaxiras. 2016. “Theory of Graphene Raman Scattering.” ACS Nano 10 (2) (February 23): 2803–2818. doi:10.1021/acsnano.5b07676.
Research Data
Abstract
Raman scattering plays a key role in unraveling the quantum dynamics of graphene, perhaps the most promising material of recent times. It is crucial to correctly interpret the meaning of the spectra. It is therefore very surprising that the widely accepted understanding of Raman scattering, i.e., Kramers–Heisenberg–Dirac theory, has never been applied to graphene. Doing so here, a remarkable mechanism we term“transition sliding” is uncovered, explaining the uncommon brightness of overtones in graphene. Graphene’s dispersive and fixed Raman bands, missing bands, defect density and laser frequency dependence of band intensities, widths of overtone bands, Stokes, anti-Stokes anomalies, and other known properties emerge simply and directly.
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Keywords
quantum chemistry, Raman spectroscopy, resonance theory, theoretical chemistry, UV−vis spectroscopy
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