Herein, intervalley scattering is exploited to account for anomalous antiresonances in the infrared spectra of doped and disordered single layer graphene. We present infrared spectroscopy measurements of graphene grafted with iodophenyl moieties in both reflection microscopy and transmission configurations. Asymmetric transparency windows at energies corresponding to phonon modes near the {\Gamma} and K points are observed, in contrast to the featureless spectrum of pristine graphene. These asymmetric antiresonances are demonstrated to vary as a function of the chemical potential. We propose a model which involves coherent intraband scattering with defects and phonons, thus relaxing the optical selection rule forbidding access to q= {\Gamma} phonons. This interpretation of the new phenomenon is supported by our numerical simulations that reproduce the experimental features.
@article{arxiv.1407.8141,
title = {Phonon-Induced Transparency in Functionalized Single Layer Graphene},
author = {Bruno Rousseau and François Lapointe and Minh Nguyen and Maxime Biron and Etienne Gaufrès and Saman Choubak and Zheng Han and Vincent Bouchiat and Patrick Desjardins and Michel Côté and Richard Martel},
journal= {arXiv preprint arXiv:1407.8141},
year = {2015}
}