Regulating^(*)COOH intermediate via amino alkylation engineering for exceptionally effective photocatalytic CO_(2) reduction

Photocatalytic reduction of CO_(2) into fuel represents a promising approach for achieving carbon neutrality,while realizing high selectivity in this process is challenging due to uncontrollable reaction intermediate and retarded desorption of target products.Engineering the interface microenvironment of catalysts has been proposed as a strategy to exert a significant influence on reaction outcomes,yet it remains a significant challenge.In this study,amino alkylation was successfully integrated into the melem unit of polymeric carbon nitrides(PCN),which could efficiently drive the photocatalytic CO_(2) reduction.Experimental characterization and theoretical calculations revealed that the introduction of amino alkylation lowers the energy barrier for CO_(2) reduction into^(*)COOH intermediate,transforming the adsorption of^(*)COOH intermediate from the endothermic to an exothermic process.Notably,the as-prepared materials demonstrated outstanding performance in photocatalytic CO_(2) reduction,yielding CO_(2)at a rate of 152.8μmol h^(-1) with a high selectivity of 95.4%and a quantum efficiency of 6.6%.

理论设计和实验研究吡啶掺杂聚合氮化碳提升光催化CO_(2)还原性能

光催化CO_(2)还原是利用太阳光和水将CO_(2)转化为高价值化学品或燃料(如CO、甲醇、甲烷等),被认为是解决CO_(2)问题的理想途径之一.CO_(2)分子中C=O离解能高而活化困难,且光催化CO_(2)还原涉及多质子耦合多电子转移过程且产物多样,因而研制效率高且选择性好的光催化剂是该技术的关键.聚合物氮化碳(PCN)作为一种结构可调的有机光催化剂,具有化学稳定性好且能带位置适宜于还原CO_(2)的优势,是一种具有发展潜力的CO_(2)还原光催化剂;但是PCN也存在因其禁带宽度较大而对可见光响应范围有限以及因其结构由三均三嗪单元构成而缺乏足够活性位点来吸附和活化CO_(2)等不足.目前在提升PCN的光催化CO_(2)还原性能方面已有不少研究,但所得的PCN基光催化剂在效率和选择性上仍处于较低水平.考虑到光催化CO_(2)还原涉及复杂的热力学和动力学要求,对基于PCN的光催化剂进行精准设计和研究是非常必要的,这有望获得同时具有可见光吸收增强、光生载流子复合减少、吸附和活化CO_(2)的位点增加以及能带位置适宜等特性的高性能光催化剂.为此,本论文采用理论设计与实验研究相结合的方法,以吡啶掺杂PCN为模型,研制了一种用于CO_(2)还原的高性能PCN基光催化剂.本文设计了将吡啶掺杂到PCN结构单元中不同位置的两种结构,并运用理论计算确定其中禁带宽度较窄、更利于光生载流子分离、更有助于CO_(2)吸附和活化以及总能量较低的结构作为最优结构.然后,采用尿素与适量的2-氨基吡啶共聚的方法,制备了吡啶掺杂的PCN样品,并通过一系列表征确定结构设计成功.还测定了所得吡啶掺杂PCN样品的光学和光电化学特性,评价了它们光催化CO_(2)还原的活性和选择性.最后,通过理论计算和实验研究,阐明了该吡啶掺杂PCN光催化剂的性能增强机制及其光催化还原CO_(2)的反应路径.结果表明,以CO(bpy)_(2)为助催化剂,本文制备的吡啶掺杂PCN(CN-5%AP)光催化剂不仅取得了较高的CO产量,而且还获得99.6%的CO选择性,在λ=420 nm处的表观量子效率可达2.86%.研究表明,该吡啶掺杂的PCN光催化性能增强主要源于其提升的CO_(2)吸附容量以及对CO_(2)还原为CO反应的促进.综上,本工作为设计和制备实现高效CO_(2)还原的光催化剂提供了参考.