Xie Bingqiao, Zhu Yi Fen, Shakeri Mahdi, Jin Seongmin, O'Connell George, Saha Sankhadip, Mensi Mounir, Kumar Priyank V, Luterbacher Jeremy S, Lovell Emma C, Amal Rose, Kröcher Oliver
Institute of Chemical Sciences and Engineering (ISIC), École Polytechnique Fédérale de Lausanne (EPFL), Lausanne 1015, Switzerland.
School of Chemical Engineering, UNSW, Kensington, Sydney, NSW 2052, Australia.
J Am Chem Soc. 2025 Sep 10;147(36):32649-32661. doi: 10.1021/jacs.5c07701. Epub 2025 Sep 1.
The limited mechanistic understanding and ambiguous structure-performance relationships have hindered the optimization of Cu-based catalysts for the reverse water-gas shift (rWGS) reaction. Here, we report a flame spray pyrolysis (FSP)-derived Cu-CeO catalyst featuring highly dispersed, surface-substituted Cu species (CuCeO) anchored on a defect-rich ceria matrix. This catalyst demonstrates excellent stability and outstanding rWGS activity at 600 °C, achieving a CO production rate of 8094 mmol/g/h, surpassing the conventional Cu-CeO catalyst and other reported rWGS catalysts. In situ spectroscopic analyses, supported by DFT calculations, reveal three parallel reaction pathways in which carboxylate- and formate-mediated routes proceed at distinct active sites. A clear structure-activity correlation is established across Cu, Cu, and ceria defect sites in the FSP-derived catalysts. Notably, a previously underexplored carboxylate-mediated pathway, facilitated on the surface-substituted Cu structure, is identified as the dominant route, featuring a significantly lower apparent activation energy (20-30 kJ/mol) compared to the classical formate pathway.
对机理的理解有限以及结构-性能关系不明确,阻碍了用于逆水煤气变换(rWGS)反应的铜基催化剂的优化。在此,我们报道了一种通过火焰喷雾热解(FSP)制备的Cu-CeO催化剂,其具有高度分散的、表面取代的铜物种(CuCeO),锚定在富含缺陷的二氧化铈基体上。该催化剂在600℃时表现出优异的稳定性和出色的rWGS活性,一氧化碳产率达到8094 mmol/g/h,超过了传统的Cu-CeO催化剂和其他报道的rWGS催化剂。在密度泛函理论(DFT)计算的支持下,原位光谱分析揭示了三条平行的反应途径,其中羧酸盐介导和甲酸盐介导的途径在不同的活性位点进行。在FSP制备的催化剂中,跨越铜、铜和二氧化铈缺陷位点建立了明确的结构-活性关系。值得注意的是,在表面取代的铜结构上促进的一条先前未被充分探索的羧酸盐介导途径被确定为主要途径,与经典的甲酸盐途径相比,其表观活化能显著更低(20 - 30 kJ/mol)。
