锰掺杂提升镍基CO2甲烷化催化剂抗硫中毒的性能与机理研究OA
Manganese doping improves the sulfur resistance of nickel-based catalysts for CO2 methanation
燃煤电厂作为CO2主要排放源,其碳减排在"双碳"目标下备受关注.CO2甲烷化被认为是实现碳循环利用最实用有效的途径,但当前CO2甲烷化领域最广泛采用的镍基催化剂,易因烟气中的SO2发生硫中毒而失活.本研究采用湿浸渍法制备了一系列Mn改性Ni/γ-Al2O3催化剂,该催化剂具有抗硫中毒性能.通过XRD、XPS、CO2-TPD、SO2-TPD和H2-TPR等多种方法对催化剂结构和物理化学性质进行研究,阐明了其保持高反应活性的同时具备抗硫性质的机理.结果表明,4Mn-Ni/Al2O3具有最佳的催化性能和抗硫性能,CO2转化率最高达到88.27%,SO2通入3 h后,CO2转化率仅下降11.32%.机理研究表明,Mn可作为牺牲位点保护Ni位点免受硫中毒,同时Ni-Mn之间相互作用抑制了 SO2在催化剂表面的吸附,进而提升抗硫性能.该研究为燃煤含SO2烟气的CO2直接甲烷化利用提供了一条可行性方案.
Coal-fired power plants,as the primary source of CO2 emissions,have garnered significant attention for carbon reduction under the"dual carbon"goals.CO2 methanation is considered to be the most practical and effective way to achieve carbon recycling,however,the most widely used nickel-based catalysts in CO2 methanation are prone to sulfur poisoning deactivation due to SO2 in the flue gas.In this paper,a series of Mn-modified Ni/γ-Al2O3 were prepared by wet impregnation method,which had anti-sulfur poisoning properties.The structure and physicochemical properties of the catalysts were investigated using various methods such as XRD,XPS,CO2-TPD,SO2-TPD and H2-TPR,and the mechanism by which the maintain high catalytic activity while possessing sulfur resistance was elucidated.The results show that 4Mn-Ni/Al2O3 exhibits the best catalytic performance and sulfur resistance,with a maximum CO2 conversion rate of 88.27%.After 3 h of SO2 exposure,the CO2 conversion rate only decreased by 11.32%.Mechanistic studies indicate that Mn can serve as a sacrificial site to protect Ni sites from sulfur poisoning,while the interaction between Ni and Mn suppresses the adsorption of SO2 on the catalyst surface,thereby enhancing sulfur resistance.This research provides a feasible solution for the direct methanation of CO2 from coal-fired SO2 flue gas.
申瑛;许紫阳;陈亮;王春波
华北电力大学动力工程系,河北保定 071003||华北电力大学河北省低碳高效发电技术重点实验室,河北保定 071003华北电力大学动力工程系,河北保定 071003||华北电力大学河北省低碳高效发电技术重点实验室,河北保定 071003华北电力大学动力工程系,河北保定 071003||华北电力大学河北省低碳高效发电技术重点实验室,河北保定 071003华北电力大学动力工程系,河北保定 071003||华北电力大学河北省低碳高效发电技术重点实验室,河北保定 071003
化学化工
催化活性催化剂抗硫性能活性位点甲烷
catalytic activitycatalystsulfur resistanceactive sitemethane
《燃料化学学报(中英文)》 2026 (1)
67-77,11
Supported by the National Natural Science Foundation of China(52306135)and Natural Science Foundation of Hebei Provience(E2024502035).国家自然科学基金(52306135)和河北省自然科学基金(E2024502035)资助
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