化学
催化作用
乙醇
兴奋剂
选择性
活动站点
钇
红外光谱学
无定形固体
密度泛函理论
从头算
无机化学
原位
荧光
多相催化
光谱学
乙醇燃料
组合化学
光化学
吸收光谱法
纳米技术
电催化剂
荧光光谱法
基体隔离
选择性还原
化学工程
基质(化学分析)
碳纤维
吸收(声学)
作者
Wei Shen,Peng Chen,Qiujin Xia,Yang Hu,Xiaogang Sun,Yizhen Ye,Haodian Xie,Shanshan Wu,Nan Zhang,Li An,Yao Zheng,Shouheng Sun,Pinxian Xi,Chun‐Hua Yan
摘要
High Resolution Image Download MS PowerPoint Slide The carbon dioxide reduction reaction (CO 2 RR) offers a promising route for sustainable energy conversion. However, achieving high selectivity toward targeted C–C products such as ethanol remains a significant challenge. This limitation stems from the structural complexity and design constraints of efficient Cu-based catalysts, as well as uncertainties regarding the nature of active sites. In this study, we present a rare-earth doping strategy in which yttrium (Y) facilitates the formation of amorphous, low-valent Cu species - identified as key contributors to ethanol selectivity. Using this Y–CuS catalyst, we demonstrate direct ethanol synthesis from CO 2 at a current density of 400 mA cm –2, achieving a Faraday efficiency of 52%. Notably, when the ethanol-producing current density exceeds 200 mA cm –2, the energy efficiency reaches 23.8%. In situ infrared spectroscopy-mass spectrometry, combined with time-resolved absorption measurements, reveals that Y incorporation into the Cu–S matrix enhances the generation of ethanol-related intermediates by increasing the density of active sites. Complementary in situ X-ray diffraction (XRD) and fluorescence spectroscopy further confirm that the amorphous low-valent Cu species serve as the primary active sites for selective ethanol production, which is further supported by X-ray spectroscopy and ab initio molecular dynamics simulations. Our findings establish a new catalyst design strategy, demonstrating that rare-earth doping can induce the formation of highly active amorphous Cu sites. This approach offers a sustainable and generalizable pathway for efficient CO 2 conversion to ethanol and potentially other value-added products.
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