High-performance Cu/ZnO/Al2O3 catalysts for methanol steam reforming with enhanced Cu-ZnO synergy ef

来源 :能源化学 | 被引量 : 0次 | 上传用户:ciweiqiu
下载到本地 , 更方便阅读
声明 : 本文档内容版权归属内容提供方 , 如果您对本文有版权争议 , 可与客服联系进行内容授权或下架
论文部分内容阅读
Methanol steam reforming (MSR) is an attractive approach to produce hydrogen for fuel cells.Due to the limited catalyst loading volume and frequent start-ups and shut-downs on board,it is highly desired to develop an extremely active and robust catalyst.Herein,on the basis of industrial Cu/ZnO/Al2O3 catalysts,a series of CuZnAl-xMg catalysts with enhanced Cu-ZnO synergy were synthesized via magnesium assisted strategy.The incorporation of magnesium was found to be beneficial to the enhancement of cat-alytic activity and stability of catalyst.A combination of complementary characterizations (e.g.XRD,H2-TPR,N2O chemisorption,TEM,XPS analysis etc.) proves that isomorphous substitution of Cu2+ in mala-chite phase gives rise to more dispersive Cu and ZnO NPs,and the increased Cu+/Cu0 ratio indicates the strengthened Cu-ZnO synergy effect,which leads to the boosted stability during the thermal treatment.
其他文献
Aqueous battery-supercapacitor hybrid devices (BSHs) are of great importance to enrich electrochemical energy storage systems with both high energy and power densities.However,further improvement of BSHs in aqueous electrolytes is greatly hampered by oper
With the rapid development of integrated and miniaturized electronics,the planar energy storage devices with high capacitance and energy density are in enormous demand.Hence,the advanced manufacture and fast fabrication of microscale planar energy units a
Inorganic CsPbI2Br perovskite solar cells (PSCs) have a tremendous development in last few years due to the trade-off between the excellent optoelectronic properties and the relatively outstanding stability.Herein,we demonstrated a strategy of secondary c
Three-dimensional (3D) frameworks have received much attention as an effective modification strategy for next-generation high-energy-density lithium metal batteries.However,the top-growth mode of lithium (Li) on the 3D framework remains a tough challenge,
In this study,a CO2 capture material in the form of liquid-like adsorbents (LLAs) is developed to overcome the limitations of conventional types of adsorbents.The increase in indoor activities necessitates the cap-ture of CO2 in enclosed indoor spaces.Ind
Uncontrollable Li dendrite growth and infinite volume fluctuation during durative plating and stripping process gravely hinder the application of metallic Li electrode in lithium-oxygen batteries.Herein,oxygen vacancy-rich TiO2 (Vo-TiO2) nanoparticles (NP
Regulation of the Li2CO3 byproduct is the most critical challenge in the field of non-aqueous Li-O2 bat-teries.Although considerable efforts have been devoted to preventing Li2CO3 formation,no approaches have suggested the ultimate solution of utilizing t
Indium oxide supported nickel catalyst has been experimentally confirmed to be highly active for CO2 hydrogenation towards methanol.In this work,the reaction mechanism for CO2 hydrogenation to metha-nol has been investigated on a model Ni/In2O3 catalyst,i
Lithium metal batteries have obtained increasing interest due to their high specific capacity.Nonetheless,the growth of lithium dendrites brings safety risks to batteries and further deteriorates the performance.Herein,we explore diethyl phenylphosphonite
Metal halide perovskites are emerging as the most promising candidate for the next-generation Photovoltaics (PV) materials,due to their superior optoelectronic properties and low cost.However,the resulting Perovskite solar cells (PSCs) suffer from poor st