光热治疗
二氧化碳重整
合成气
催化作用
材料科学
化学工程
纳米颗粒
无定形固体
甲烷
碳纤维
无定形碳
纳米技术
氧气
电子转移
光热效应
纳米结构
载流子
光化学
氧化物
纳米晶
化学
沉积(地质)
薄膜
蒸汽重整
表面工程
析氧
金属
作者
Bifang Li,Li Zhang,Bo Su,Jiabin Chen,Kunlong Liu,Chengyang Feng,Xiahui Lin,Yidong Hou,Huabin Zhang,Sibo Wang
摘要
ABSTRACT Photothermal dry reforming of methane (DRM) enables solar‐driven upgrading of CH 4 and CO 2 , yet its efficiency and durability are hindered by carbon deposition and poorly defined photochemical contributions. Here, we demonstrate a charge‐directed photothermal DRM catalyst composed of Rh nanoparticles supported on TiO x ‐functionalized TiC, where interfacial TiO x domains play a critical role by coupling directional photocarrier flow with adaptive oxygen chemistry. Upon illumination, metallic TiC generates charge carriers that transfer electrons to Rh sites while steering holes to TiO x surface oxygens. This charge‐directed interfacial chemistry selectively lowers the barrier for *OCH 3 formation, the potential‐determining step, thus suppressing *CH 3 over‐dehydrogenation and mitigating carbon formation. Concurrently, CO 2 activation at oxygen vacancies within TiO x regions restocks surface oxygens, closing a regenerative photothermal Mars–van Krevelen cycle. As a result, the catalyst delivers high syngas production rates (CO: 17.5 mol g Rh −1 h −1 , H 2 : 10.5 mol g Rh −1 h −1 ), attains a light‐to‐chemical energy efficiency of 29%, and operates stably for over 100 h without coking. This work highlights the mechanistic importance of amorphous TiO x interface in charge‐directed photothermal DRM and provides design insights for developing coking‐resistant reforming catalysts.
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