Fe-MnO_x催化过氧化氢氧化酸性橙-7研究

采用共沉淀法制备Fe-MnO_x催化剂进行催化过氧化氢氧化降解酸性橙-7的研究,考察了酸性橙-7初始含量、催化剂投加量、溶液初始pH对酸性橙-7降解的影响,并探讨了反应机理。结果表明,H_2O_2的浓度为3.7 mmol/L、Fe-MnO_x投加量100 mg/L时,当酸性橙-7初始质量浓度高于15 mg/L时去除率随酸性橙-7含量升高而降低;酸性橙-7初始量浓度低于15 mg/L时去除率随酸性橙-7含量升高而升高。溶液初始pH对酸性橙-7的去除有显著影响,pH为2时酸性橙-7有最佳去除率42.4%。当反应溶液中加入羟基自由基抑制剂叔丁醇后,酸性橙-7的去除率明显降低,证明体系中的主要氧化物种为羟基自由基。

MnO_x助剂对Fe/SiO_2催化剂费-托合成制低碳烯烃动力学的影响

探讨了MnOx助剂对Fe/SiO2催化剂经由费-托反应（Fischer-Tropsch）制备低碳烯烃（FTO）的影响。通过浸渍法制备了Fe20/SiO2和Fe20-Mn1.0/SiO2催化剂,结果表明MnOx助剂显著提升了CO转化率和C2～C4烯烃的时空收率。程序升温吸附实验表明MnOx助剂增加了Fe基催化剂表面碱性,促进了CO的解离吸附。运用幂指数模型,研究了Fe20/SiO2和Fe20-Mn1.0/SiO2催化剂上FTO反应动力学,得到了各产物生成活化能与H2/CO反应级数。最后,结合动力学研究与程序升温表征结果,对Fe基催化剂FTO反应机理,尤其是MnOx助剂提高Fe20/SiO2催化剂上低碳烯烃选择性的作用进行了讨论。

Fe对MnO_x催化剂低温SCR脱硝性能的影响

采用共沉淀法制备一系列Fe改性的MnOx催化剂,在固定床模拟燃煤烟气气氛下考察其脱硝活性,同时借助N2吸附及XRD等研究Fe添加对MnOx催化剂低温SCR脱硝活性的促进机理。结果表明,Fe的添加显著提高了MnOx的低温NOx转化率,并将其活性温度窗口向低温段拓宽了55℃;其中,Fe0.3Mn0.7Ox催化剂在30 000h-1下具有最佳低温SCR活性,自90℃其NOx转化率均高于95%;铁、锰组分间的协同作用能提高催化剂中锰氧化物的分散度,增大催化剂的比表面积和比孔容并优化其孔径分布,进而提高MnOx催化剂的低温SCR脱硝活性。

Fe、Ce改性锰钛催化剂的制备及其低温脱硝性能研究

为解决目前高温脱硝催化剂温区窄、易失活和中毒的问题,制备了Fe,Ce改性的MnOx-TiO2低温脱硝催化剂。0.08Fe0.05Ce/MnOx-TiO2催化剂脱硝效率达到90%以上的温区最宽,达到了99~374℃。XRD、BET测试表明催化剂的活性组分在TiO2载体上的分散性提高,催化剂的比表面积增加。XPS分析结果表明催化剂表面化学吸附氧增加,Mn以MnO2和Mn2O3的形式存在,Ce和Fe的加入促进了MnO2和Mn2O3之间的转化,有利于脱硝反应的进行。H2-TPR、NH3-TPD分析结果表明催化剂表面的弱酸和中强酸含量提高,低温氧化还原能力提高。

Solvothermal preparation of Mn-based catalysts for simultaneous removal of 1,2-dichlorobenzene and furan

In this study,Mn-based bimetallic oxide catalysts were synthesized via the solvothermal method.Different metals(Ce,Co and Fe)exhibited a great impact on the physicochemical properties of catalysts,resulting in different catalytic activities for the simultaneous removal of 1,2-dichlorobenzene(1,2-DCB)and furan,as a model of polychlorinated dibenzodioxins and dibenzo-furans(PCDD/Fs).Fe–MnOx presented the best catalytic activity,with a removal efficiency of 62%for 1,2-DCB and 100%for furan at 240℃.Several analytical techniques were employed,namely,Brunauer–Emmett–Teller(BET),X-ray diffraction(XRD),scanning electron microscope(SEM),X-ray photoelectron spectroscopy(XPS),H_(2)temperature-programmed reduction(H_(2)-TPR),and ammonia temperature programmed desorption(NH_(3)-TPD).Compared with pure MnOx catalysts,Fe–MnOx shows a higher specific surface area of 117.9 m^(2)/g.SEM observations showed flower-like nanosheet structures for Fe–MnOx.XPS analysis indicated that Mn^(4+)/Mn^(3+)and active oxygen play the key roles in the catalytic oxidation of 1,2-DCB and furan.The catalytic activity,selectivity and stability of Mn-based bimetallic oxide catalysts for the oxidation of 1,2-DCB and furan were tested.Competition exists between 1,2-DCB and furan such that the adsorption of furan occurs prior to 1,2-DCB.