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Selectivity Reversal from CO to Ethylene Products in CO 2 Photoreduction via Electronic Modulation of SnS 2 Using a Vinyl-Bridged Porous Organic Polymer

化学 选择性 乙烯 聚合物 调制(音乐) 化学工程 多孔性 光化学 聚乙烯 有机聚合物 多孔介质 无机化学 高分子化学 有机化学
作者
Subhajit Chakraborty,Bishal Boro,S. A. Keishana Navodye,Rajib Ghosh,Abhijit Shrotri,Rajashri Urkude,Geetansh Chawla,C. P. Vinod,G. T. Kasun Kalhara Gunasooriya,John Mondal,Sebastian C. Peter
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:148 (25): 25669-25684
标识
DOI:10.1021/jacs.6c02822
摘要

Developing an efficient and robust photocatalyst for optimal C 2+ product generation from carbon dioxide (CO 2 ) is a pressing need in advancing solar fuel production. In this study, we designed an ionic vinylene-bridged conjugated porous organic polymer (Py-POP) enriched with charged pyridine groups via a quaternization-promoted Knoevenagel condensation reaction. The resulting positively charged polymeric framework with shape-persistent nanochannels enabled the uniform assembly of SnS 2 units through ionic interactions mediated by amino and sulfhydryl groups. The hybrid porous photopolymer (SnS 2 @Py-POP) converts CO 2 into ethylene with a rate of 34.7 μmol g –1 h –1 with a selectivity of ethylene around 78.7% under visible light photoirradiation, which outperforms all the C 2 selective Sn-based photocatalysts. Our findings principally sheds light on the mechanism of selectivity reversal (from C 1 to C 2 product) by hybrid catalyst framework engineering. In-depth investigations by synchrotron-based X-ray absorption spectroscopy (XAS) and morphological analysis via high-resolution transmission electron microscopy (HRTEM) reveal the nature of interaction for hybrid heterostructure formation within the porous network. Electron transfer pathways were mapped using time-resolved photoluminescence (TRPL) and transient absorption spectroscopy (TAS), which revealed a Z-scheme electron transfer mechanism. This mechanism facilitates enhanced electron accumulation on the SnS 2 layer, promoting efficient CO 2 activation and subsequent C–C coupling, ultimately leading to ethylene formation. Furthermore, the ethylene formation mechanism has been investigated in detail by time-resolved diffuse reflectance infrared spectroscopy (TR-DRIFTS), corroborated with density functional theory (DFT). This study opens a new avenue for achieving selectivity reversal in a C 1 selective photocatalyst through electronic modulation enabled by the formation of an inorganic–organic hybrid heterostructure.
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