This study explores the controllable synthesis of CuAlO_(2) using copper hydroxide and pseudo-boehmite powders as raw materials via a simple solid-phase ball milling method,along with its catalytic performance investi...This study explores the controllable synthesis of CuAlO_(2) using copper hydroxide and pseudo-boehmite powders as raw materials via a simple solid-phase ball milling method,along with its catalytic performance investigation in methanol steam reforming(MSR).Various catalysts were prepared under different conditions,such as calcination temperature,calcination atmosphere,and heating rate.Characterization techniques including BET,XRD,XPS,SEM and H2-TPR were employed to analyze the samples.The results revealed significant effects of calcination temperature on the phase compositions,specific surface area,reduction performance,and surface properties of the CA-T catalysts.Based on the findings,a synthesis route of CuAlO_(2) via the solid-phase method was proposed,highlighting the importance of high calcination temperature,nitrogen atmosphere,and low heating rate for CuAlO_(2) formation.Catalytic evaluation data demonstrated that CuAlO_(2) could catalyze MSR without pre-reduction,with the catalytic performance of CA-T catalysts being notably influenced by calcination temperature.Among the prepared catalysts,the CA-1100 catalyst exhibited the highest catalytic activity and stability.The findings of this study might be useful for the further study of the catalytic material for sustained release catalysis,including the synthesis of catalytic materials and the regulation of sustained release catalytic performance.展开更多
In this work,we investigated the methanol steam reforming(MSR)reaction(CH_(3)OH+H_(2)O→CO_(2)+3H_(2))catalyzed byα-MoC by means of density functional theory calculations.The adsorption behavior of the relevant inter...In this work,we investigated the methanol steam reforming(MSR)reaction(CH_(3)OH+H_(2)O→CO_(2)+3H_(2))catalyzed byα-MoC by means of density functional theory calculations.The adsorption behavior of the relevant intermediates and the kinetics of the elementary steps in the MSR reaction are systematically investigated.The results show that,on theα-MoC(100)surface,the O−H bond cleavage of CH3OH leads to CH3O,which subsequently dehydrogenates to CH_(2)O.Then,the formation of CH_(2)OOH between CH_(2)O and OH is favored over the decomposition to CHO and H.The sequential dehydrogenation of CH_(2)OOH results in a high selectivity for CO_(2).In contrast,the over-strong adsorption of the CH_(2)O intermediate on theα-MoC(111)surface leads to its dehydrogenation to CO product.In addition,we found that OH species,which is produced from the facile water activation,help the O−H bond breaking of intermediates by lowering the reaction energy barrier.This work not only reveals the catalytic role played byα-MoC(100)in the MSR reaction,but also provides theoretical guidance for the design ofα-MoC-based catalysts.展开更多
基金supported by the Scientific Research Foundation for High-level Talents of Anhui University of Science and Technology(2023yjrc51)the National Natural Science Foundation of China(22172184)+2 种基金the Foundation of State Key Laboratory of Coal Conversion(J24-25-603)the Fundamental Research Project of ICC-CAS(SCJC-DT-2023-01)Weiqiao-UCAS Special Projects on Low-Carbon Technology Development(GYY-DTFZ-2022-015)。
文摘This study explores the controllable synthesis of CuAlO_(2) using copper hydroxide and pseudo-boehmite powders as raw materials via a simple solid-phase ball milling method,along with its catalytic performance investigation in methanol steam reforming(MSR).Various catalysts were prepared under different conditions,such as calcination temperature,calcination atmosphere,and heating rate.Characterization techniques including BET,XRD,XPS,SEM and H2-TPR were employed to analyze the samples.The results revealed significant effects of calcination temperature on the phase compositions,specific surface area,reduction performance,and surface properties of the CA-T catalysts.Based on the findings,a synthesis route of CuAlO_(2) via the solid-phase method was proposed,highlighting the importance of high calcination temperature,nitrogen atmosphere,and low heating rate for CuAlO_(2) formation.Catalytic evaluation data demonstrated that CuAlO_(2) could catalyze MSR without pre-reduction,with the catalytic performance of CA-T catalysts being notably influenced by calcination temperature.Among the prepared catalysts,the CA-1100 catalyst exhibited the highest catalytic activity and stability.The findings of this study might be useful for the further study of the catalytic material for sustained release catalysis,including the synthesis of catalytic materials and the regulation of sustained release catalytic performance.
基金This work is supported by the National Natural Science Foundation of China(No.21973013)the National Natural Science Foundation of Fujian Province,China(No.2020J02025)the“Chuying Program”for the Top Young Talents of Fujian Province.Numerical computations were performed on Hefei Advanced Computing Center.
文摘In this work,we investigated the methanol steam reforming(MSR)reaction(CH_(3)OH+H_(2)O→CO_(2)+3H_(2))catalyzed byα-MoC by means of density functional theory calculations.The adsorption behavior of the relevant intermediates and the kinetics of the elementary steps in the MSR reaction are systematically investigated.The results show that,on theα-MoC(100)surface,the O−H bond cleavage of CH3OH leads to CH3O,which subsequently dehydrogenates to CH_(2)O.Then,the formation of CH_(2)OOH between CH_(2)O and OH is favored over the decomposition to CHO and H.The sequential dehydrogenation of CH_(2)OOH results in a high selectivity for CO_(2).In contrast,the over-strong adsorption of the CH_(2)O intermediate on theα-MoC(111)surface leads to its dehydrogenation to CO product.In addition,we found that OH species,which is produced from the facile water activation,help the O−H bond breaking of intermediates by lowering the reaction energy barrier.This work not only reveals the catalytic role played byα-MoC(100)in the MSR reaction,but also provides theoretical guidance for the design ofα-MoC-based catalysts.
