机构地区:[1]Key Laboratory of Bioinorganic and Synthetic Chemistry of Ministry of Education,Fine Chemical Industry Research Institute,School of Chemistry,IGCME,Sun Yat-sen University,Guangzhou 510275,Guangdong,China [2]State Key Laboratory Breeding Base of Green-Chemical Synthesis Technology,Institute of Green Petroleum Processing and Light Hydrocarbon Conversion,College of Chemical Engineering,Zhejiang University of Technology,Hangzhou 310014,Zhejiang,China [3]Guangxi Key Laboratory of Petrochemical Resource Processing and Process Intensification Technology,School of Chemistry and Chemical Engineering,Guangxi University,Nanning 530004,Guangxi,China [4]State Key Laboratory of Chemical Biology and Drug Discovery,Department of Applied Biology and Chemical Technology,The Hong Kong Polytechnic University,Hunghom,Hong Kong,China [5]Guangdong Technology Research Center for Synthesis and Separation of Thermosensitive Chemicals,Guangzhou 510275,Guangdong,China
出 处:《Chinese Journal of Catalysis》2024年第11期168-180,共13页催化学报(英文)
基 金:国家重点研发项目(2020YFA0210902);广东省自然科学杰出青年基金(2022B1515020035);国家自然科学基金(22078371,U22A20428,21938001,22422815);山西省科技创新团队专项资金(202304051001007).
摘 要:Dispersing metals from nanoparticles into clusters or single atoms often exhibits unique properties such as the inhibition of structure-sensitive side reactions.Here,we reported the use of ion exchange(IE)methods and direct hydrogen reduction to achieve high dispersion of Co species on zincosilicate.The obtained 2Co/Zn-4-IE catalyst achieved an initial propane conversion of 41.4%at a temperature of 550℃in a 25%propane and 75%nitrogen atmosphere for propane dehydrogenation.Visualization of the presence of Co species within specific rings(alpha-α,beta-βand delta-δ)was obtained by aberration-corrected scanning transmission electron microscopy.A series of Fourier transform infrared spectra confirmed the anchoring of Co by specific hydroxyl groups in zincosilicate and the specific coordination environment of Co and its presence in the rings essentially as a single site.The framework Zn for the modulation of the microenvironment and the presence of Co species as Lewis acid active sites(Co-O4)was also supported by density functional theory calculations.丙烷脱氢(PDH)具有原料单一、工艺流程短、收率高、投资成本低等优点,有望成为未来丙烯扩产的主要方向.在典型的PDH技术中,OleflexTM和CatofinTM工艺分别使用了负载型PtSn/Al2O3和Cr2O3/Al2O3催化剂.然而,它们固有的缺点(主要由于铬对环境的毒性和铂的稀缺性)促使人们开发廉价高效的替代品.含Co催化剂因能更好地激活C–H裂解,尤其是以单个位点和簇的形式,受到研究者的广泛关注.通常,沸石框架Co物种在烷烃脱氢反应中表现出较高的稳定性,但由于活化温度较高,更适用于乙烷脱氢(EDH),在PDH中进一步权衡转化率-温度至关重要.此外,由于ZSM-5中框架Al的存在,通常使得催化剂具有较高的酸度,从而导致过于明显的副反应.本文针对PDH反应催化剂在丙烷转化率和活化温度权衡、催化剂长期稳定性、丙烷选择性、活性位点及反应机理研究等问题,对Co-沸石材料进行探索.受益于沸石材料催化的优势,Co-沸石材料可能产生协同效应,从而克服反应物由于载体的块状性质而无法充分接近活性位点的困难.通过用离子交换(IE)将Co物种引入硅酸锌沸石中,并进行直接H2还原,在此过程中,它们与羟基介导的框架O(尤其是框架Zn相邻O)结合,进而主要形成不饱和的单金属位点(Co-O4).硅酸锌沸石中Si-OH-Zn中的O比Si-OH对金属有更强的锚定作用,并且与浸渍法(IWI)相比,离子交换法(IE)可以更均匀、精确地定位到框架Zn附近,从而在特定环(α和β)中形成类似框架的孤立Co物种.该方法合成的催化剂中Co物种更倾向于T8位点锁定,并以Co-O4的形式形成L酸、充当丙烷脱氢活性位点,整体显示出较好的PDH性能.优化后的2Co/Zn-4-IE(数字代表初始投料质量比)催化剂在25%丙烷气氛中于550ºC进行丙烷脱氢时,丙烷的初始转化率达到41.4%,测试8.5 h后,转化率保持在39.5%.值得一提的是,Pt基催化剂在该反应条件下,平衡转化值通
关 键 词:Zincosilicate zeolite Anchoring effect Microenvironment modification Isolated Co site Propane dehydrogenation
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