石墨烯
化学
催化作用
碳纤维
氧化还原
氧化物
乙炔
密度泛函理论
成核
纳米技术
钙钛矿(结构)
卡宾
过渡金属
量子点
光化学
分解
反应机理
分子动力学
化学物理
氧气
维数之咒
化学工程
计算化学
过渡状态
作者
Mengxuan Zhang,Takeharu Yoshii,Qi Zhao,Yuichiro Hayasaka,Devis Di Tommaso,Hirotomo Nishihara
摘要
High Resolution Image Download MS PowerPoint Slide Achieving low-temperature graphene formation remains a major challenge in carbon materials chemistry. Here we reveal a defect-mediated catalytic mechanism in which dynamically generated oxygen vacancies on ceria (CeO 2 ) activate acetylene (C 2 H 2 ) and direct the structural evolution of carbon networks at remarkably low temperatures. The oxygen-vacancy–driven redox dynamics of CeO 2 enables C 2 H 2 decomposition to proceed at temperatures as low as 113 °C, initiating carbon nucleation and leading to graphene domain formation below 300 °C. The temperature-dependent evolution─from graphene quantum dots (GQDs, 300 °C) to aggregated graphene (450 °C) and porous graphene frameworks (600 °C)─illustrates a designable transition in carbon connectivity directed by defect chemistry. Mechanistic studies combining in situ spectroscopy, thermogravimetry, and density functional theory reveal that the reaction follows a temperature-dependent transition from a radical to a carbene pathway, governed by the oxygen-vacancy chemistry of CeO 2 . Together, these results define a defect-mediated catalytic paradigm that couples oxide redox dynamics with carbon dimensionality control, offering a general principle for low-temperature formation of graphene-based sp 2 carbon materials.
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