石墨烯
红外线的
红外光谱学
氧化物
密度泛函理论
格子(音乐)
材料科学
化学物理
谱线
吸附
分子物理学
化学
计算化学
纳米技术
物理化学
物理
光学
有机化学
声学
冶金
天文
作者
Cui Zhang,Daniel M. Dabbs,Limin Liu,İlhan A. Aksay,Roberto Car,Annabella Selloni
标识
DOI:10.1021/acs.jpcc.5b02727
摘要
Infrared spectroscopy in combination with density functional theory calculations has been widely used to characterize the structure of graphene oxide and its reduced forms. Yet, the synergistic effects of different functional groups, lattice defects, and edges on the vibrational spectra are not well understood. Here, we report first-principles calculations of the infrared spectra of graphene oxide performed on realistic, thermally equilibrated, structural models that incorporate lattice vacancies and edges along with various oxygen-containing functional groups. Models including adsorbed water are examined as well. Our results show that lattice vacancies lead to important blue and red shifts in the OH stretching and bending bands, respectively, whereas the presence of adsorbed water leaves these shifts largely unaffected. We also find unique infrared features for edge carboxyls resulting from interactions with both nearby functional groups and the graphene lattice. Comparison of the computed vibrational properties to our experiments clarifies the origin of several observed features and provides evidence that defects and edges are essential for characterizing and interpreting the infrared spectrum of graphene oxide.
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