Performance enhancement mechanism of Mn-based catalysts prepared under N_2 for NO_x removal:Evidence of the poor crystallization and oxidation of MnO_x

Among multitudinous metal‐oxide catalysts for the selective catalytic reduction of NOx with NH3(NH3‐SCR),Mn‐based catalysts have become very popular and developed rapidly in recent years because of its superior low‐temperature denitrification activity,mainly originating from multi‐valence of Mn.Most studies suggest that the catalytic activity of multi‐component oxides is superior to that of single‐component catalysts owing to the synergistic effect among the metallic elements in such materials,of which more attentions have been given to Ce as an additive owing to its powerful oxygen storage capacity,redox ability and its ready availability.As the core of SCR technology,the research points in catalyst development at the present stage of all researchers in countries mainly centralize on the optimization of active components,carriers,calcination temperature,calcination time and temperature‐raising procedure,giving little thought to the effects of the calcination atmosphere.In the present work,Ce‐modified Mn‐based catalysts were prepared by a simple impregnation method.The effects of the calcination atmosphere(N2,air or O2)on the performance of the resulting materials during NH3‐SCR and its causes of the differences were subsequently investigated and characterized using various analytical methods.Data obtained from X‐ray diffraction,thermogravimetry and temperature‐programmed reduction with hydrogen show that calcination under N2reduces both the degree of oxidation and crystallization of the MnOx.Scanning electron microscopy also demonstrates that the use of N2inhibits the growth of grains and increases the dispersion of the catalysts.In addition,the results of temperature‐programmed desorption with ammonia indicate that catalysts calcined under N2exhibit a greater quantity of acid sites.Finally,X‐ray photoelectron spectrometry and activity results demonstrate that MnOx in the lower valence states is more favorable for NH3‐SCR reactions.In conclusion,catalysts calcined under N2show superior performance during NH3‐SCR for NOx removal,allowing NO conversions up to94%at473K.

Selective catalytic oxidation of NO with O_2 over Ce-doped MnO_x/TiO_2 catalysts

A series of Ce-doped MnOx/TiO2 catalysts were prepared by impregnation method and used for catalytic oxidation of NO in the presence of excess O2. The sample with the Ce doping concentration of Ce/Mn=l/3 and calcined at 300 ℃ shows a superior activity for NO oxidation to NO2. On Ce（1）Mn（3）Ti catalyst, 58% NO conversion was obtained at 200 ℃ and 85% NO conversion at 250 ℃ with a GHSV of 41000 h-1, which was much higher than that over MnOx/TiO2 catalyst （48% at 250 ℃）. Characterization results implied that the higher activity of Ce（1）Mn（3）Ti could be attributed to the enrichment of well-dispersed MnO2 on the surface and the abundance of Mn3＋ and Zi3＋ species. The addition of Ce into MnO2/TiO2 could improve oxygen storage capacity and facilitate oxygen mobility of the catalyst as shown by PL and ESR, so that its activity for NO oxidation could be enhanced. The effect of H2O and SO2 on the catalyst activity was also investigated.

Transition Metal Doped MnO_x-CeO₂Catalysts by Ultrasonic Immersing for Selective Catalytic Reduction of NO with NH₃at Low Temperature

Transition metals doped Mn-based catalysts were prepared via ultrasonic immersing method for the selective catalytic reduction (SCR) of NOx from fuel gas. The Catalysts’ DeNOx efficiency and tolerance to sulfur were investigated in the paper. XRD results demonstrate high dispersion of Mn, Ce and M (Pr, Y, Zr, W) elements on TiO2 carrier, which is favor for reduction of active materials content. Mn-Ce-W catalyst presents uniform particle size about 500 nm to 800 nm from SEM pictures and shows the best NOx conversion of 93.2% at 200°C and 98.4% at 250°C, respectively. Sulfur tolerance analysis indicated that transition metals M can improve the catalysts’ performance when 0.01% SO2 exists in the fuel gas, because metal doping into the Mn-Ce catalyst can inhibit the sulfate deposition, especially metal sulfate, on the catalyst, which can be seen from the Fourier infrared spectrum.

Mn^(2+)掺杂对YAG∶Ce^(3+)荧光陶瓷发光性能的影响

过渡族金属Mn^(2+)掺杂的石榴石荧光陶瓷被认为是实现高显色激光照明的候选材料。然而,由于Mn^(2+)在不同配位环境下离子半径的多样性,Mn^(2+)掺杂石榴石陶瓷体系设计方案尚不明确。本文采用真空烧结技术制备得到不同浓度Mn^(2+)掺杂的YAG∶Ce^(3+)荧光陶瓷,并将Mn^(2+)分别设计进入八面体(OC)和十二面体(DO)格位。通过表征样品物相和显微结构、光致发光、荧光寿命、量子效率等,并通过LD激光器激发对荧光陶瓷的发光性能进行研究。实验结果表明,在添加电荷与体积补偿剂SiO_(2)的前提下,相比Mn^(2+)进入十二面体格位,Mn^(2+)进入八面体后石榴石的晶体结构更加稳定。因此,当Mn^(2+)的浓度控制在0.5%^(6)%(at)范围内,OC系列样品的量子效率高于DO系列样品。此外,OC系列样品的PL谱中位于588 nm和725 nm处的发射峰分别对应于Mn^(2+)占据八面体和十二面体格位的^(4)T_(1)→^(6)A_(1)电子跃迁,而DO系列样品中位于572 nm处的发射峰则源于Mn^(2+)占据扭曲的十二面体格位产生的电子跃迁。得益于Ce^(3+)→Mn^(2+)间高效的能量传递,将浓度为6%(at)的Mn^(2+)设计进入YAG∶Ce^(3+)中八面体格位制得荧光陶瓷,封装得到的激光白光光源的显色指数为70.8,相对色温为5117 K。本文对于Mn^(2+)掺杂的石榴石发光材料的开发研究是有力补充,也为提升YAG∶Ce^(3+)荧光陶瓷光谱中的红光成分,进而提高医疗、显示等领域的激光光源的显色性能提供借鉴。

K^(+)诱导Mn-Ce固溶体增强酸性和活性氧协同促进NH_(3)-SCR

本文采用水热驱动将K离子引入制备的Mn-Ce固溶体晶格中(MnCeOx),优化其结构特征并用于NH_(3)-SCR反应.H_(2)-TPR和O_(2)-TPD结果表明,K的加入极大的弱化了Mn-O键,进而导致催化剂的还原性和氧脱附能力的提升;XPS,NH_(3)-TPD和原位红外(insitu DRIFTs)结果表明,K的引入可以增强Mn/Ce元素间的电子转移,同时提高催化剂中氧缺陷的数量以及BrФnsted酸性位对NH_(3)的吸附能力.因此,在增强的酸性位点与缺陷吸附活性氧的协同作用下,促进了催化剂MnCeK_(y)O_(x)在NH_(3)-SCR反应中的活性和反应速率.当K、Ce、Mn元素的比例为1:5:5时,在较低温度(120℃)下,MnCeK_(1)O_(x)催化剂的NO转化率为94.6%,在40~260℃的较宽温度范围内可以实现NO的高效转化.采用in situ FTIR对NH_(3)和NO原位吸附和反应过程进行分析,结果表明NH_(3)的吸附比NO更敏感.对于MnCeO_(x),NH_(3)首先吸附在Lewis酸位点上,然后结合在BrФnsted酸位点上,导致单配位基和双配位基硝酸盐同时聚集;对于Mn CeK_(1O)_(x),NH_(3)同时吸附在Lewis和BrФnsted酸性位上,其中间产物仅为单配位基硝酸盐.结果表明K离子的添加可以有效的提升Mn-Ce固溶体在NH_(3)-SCR反应中的效率.

Mn-Fe-Ce-O催化剂对助燃脱硝性能的影响

采用改进的柠檬酸络合法制备了Mn-Fe-Ce-O复合氧化物,采用XRD,H_(2)-TPR,XPS,SEM,EDS等方法分析了试样的结构与物性,并对其氧化和催化CO还原NO的性能进行了评价。实验结果表明,Mn-Fe-Ce-O复合氧化物中主要为Mn_(3)O_(4)和CeO_(2)物相,Fe和Ce的加入可增大复合氧化物的比表面积,且表面元素分布均匀,无明显集聚状态,加入Ce后复合氧化物颗粒变得细小,Mn^(3+)+Mn^(4+)含量和表面吸附氧含量增大,H_(2)-TPR还原峰向低温区偏移。Mn_(9)Fe_(1)O_(z)具有良好的氧化CO能力,400℃下CO转化率为99.56%,Mn-Fe-Ce-O复合氧化物催化CO还原NO的活性高于Mn-Fe-O复合氧化物,其中,(Mn_(9)Fe_(1))_(7)Ce_(3)O_(z)活性最高,在350℃下NO转化率为85.75%。

新型Ce掺杂MnO_(x)高效低温甲苯催化氧化性能

采用氧化-共沉淀方法制备新型Ce-MnO_(x)双金属氧化物催化剂,探究Ce,Mn活性组分间协同作用对甲苯低温催化性能的影响.通过SEM、XRD、N_(2)吸脱附曲线、XPS、EPR、H_(2)-TPR和in situ DRIFTS对催化剂物理及化学性能进行表征.结果表明,当Ce:Mn物质的量比为1:3时,CeMn_(3)O_(x)具有最低的甲苯催化温度及良好的稳定性和耐久性,且在215和233℃下分别实现甲苯的50%和90%催化,远低于MnO_(x)催化温度.表征结果证实,Ce的引入有利于调节CeMn_(3)O_(x)催化剂形成珊瑚形貌,降低催化剂结晶度形成晶相-非晶相界面,创造更多缺陷位点,提高氧空位浓度,调节氧种类促进O_(latt)←→O_(sur)←→O_(ads)的转换,增强还原性能.同时,in situ DRIFTS图谱证实了在有氧条件下,甲苯氧化遵循两条反应路径,Ⅰ:吸附→苯甲醇→苯甲醛→苯甲酸→苯酚→苯环C=C断裂→CO_(2)和H_(2)O,Ⅱ:吸附→苯环C=C断裂→环状酸酐→CO_(2)+H_(2)O两条反应路径,其中苯环C=C双键的断裂为控速步骤.

Ce改性Mn-Fe碳基催化剂低温脱硝性能及抗硫活性研究

以硝酸氧化处理后的椰壳活性炭为原料,负载硝酸锰、硝酸铁和硝酸铈等活性物质,经中低温煅烧制备Ce改性Mn-Fe碳基低温抗硫脱硝催化剂。利用固定床脱硝评价实验装置并结合BET、SEM-Mapping、XPS等表征方法研究其低温脱硝性能及抗硫活性。结果表明,Ce改性Mn-Fe碳基催化剂具有高比表面积,且表面Mn均匀分布,较高的Mn^(4+)、Ce^(3+)和表面吸附氧(O_(α))含量增强了碳基催化剂脱硝及抗硫性能。在130~220℃的脱硝效率高达99%以上;低SO_(2)浓度对催化剂脱硝性能基本无抑制作用,持续反应8 h脱硝效率仍高达88.78%。

Ce改性Ni/MnO_(x)催化剂用于甲烷干重整的研究

采用氧化还原沉淀法制备了系列xCe(100-x)MnO_(x)(简记为xC(100-x)M,x分别为0、10%、30%、50%、80%、100%)复合氧化物,通过浸渍法负载Ni制备Ni/xC(100-x)M系列催化剂。以CH_(4)干重整反应制合成气为模型反应,研究Ce与Mn质量比对Ni/CeMnO_(x)催化剂活性的影响。结果表明,在Ni/MnO_(x)催化剂中引入Ce助剂,提高了催化剂的比表面积和表面碱性位点数量,改善了催化剂的还原能力。在系列Ni/CeMnO_(x)催化剂中,Ce与Mn质量比对反应活性有着显著的影响,Ce质量分数的增加有利于提高CH_(4)和CO_(2)转化率,在反应温度为700℃和V(CH_(4))/V(CO_(2))=1∶1的条件下,Ni80C20M催化剂的CH_(4)和CO_(2)转化率相对较高,CH_(4)转化率为73.90%,CO_(2)转化率为79.38%。

Evaluation of H2 Influence on the Evolution Mechanism of NOx Storage and Reduction over Pt–Ba–Ce/c-Al2O3 Catalysts

In this investigation, Pt–Ba–Ce/c-Al2O3 catalysts were prepared by incipient wetness impregnation and experiments were performed to evaluate the influence of H2 on the evolution mechanism of nitrogen oxides (NOx) storage and reduction (NSR). The physical and chemical properties of the Pt–Ba–Ce/c- Al2O3 catalysts were studied using a combination of characterization techniques, which showed that PtOx, CeO2, and BaCO3, whose peaks were observed in X-ray diffraction (XRD) spectra, dispersed well on the c-Al2O3, as shown by transmission electron microscope (TEM), and that the difference between Ce3+ and Ce4+, as detected by X-ray photoelectron spectroscopy (XPS), facilitated the migration of active oxygen over the catalyst. In the process of a complete NSR experiment, the NOx storage capability was greatly enhanced in the temperature range of 250–350℃, and reached a maximum value of 315.3μmol·gcat^-1 at 350℃, which was ascribed to the increase in NO2 yield. In a lean and rich cycling experiment, the results showed that NOx storage efficiency and conversion were increased when the time of H2 exposure (i.e., 30, 45, and 60 s) was extended. The maximum NOx conversion of the catalyst reached 83.5% when the duration of the lean and rich phases was 240 and 60 s, respectively. The results revealed that increasing the content of H2 by an appropriate amount was favorable to the NSR mechanism due to increased decomposition of nitrate or nitrite, and the refreshing of trapping sites for the next cycle of NSR.

Effects of Ce/Zr ratio on the structure and performances of Co-Ce_(1-x)Zr_xO_2 catalysts for carbon dioxide reforming of methane

The Co-incorporated Ce1-xZrxO2 catalysts were prepared by co-precipitation for carbon dioxide reforming of methane.The ratio of Ce to Zr was varied to optimize the performances of co-precipitated Co-Ce-Zr-Ox catalysts.The prepared catalysts were characterized by various physico-chemical characterization techniques including TPR,X-ray diffraction,N2 adsorption at low temperature,XPS and CO2-TPSR.The co-precipitated Co-Ce0.8Zr0.2O2 sample containing 16% CoO exhibited a higher catalytic activity among the five catalysts,and the activity was maintained without significant loss during the reaction for 60 h.Under the conditions of 750 ℃,0.1 MPa,36000 ml/（h gcat）,and CO2/CH4 molar ratio of 1：1,the CO2 conversion over this catalyst was 75% while the CH4 conversion was 67%.The cubic Ce0.8Zr0.2O2 facilitated a higher dispersion and a higher reducibility of the cobalt component,and the apparent activation energy for Co-Ce0.8Zr0.2O2 sample was 49.1 kJ/mol in the CO2/CH4 reforming reaction.As a result,the Co-Ce0.8Zr0.2O2 sample exhibited a higher activity and stability for the reforming of CH4 with CO2.

Promoter of (Ce-Zr)O_2 Solid Solution Modified by Praseodymia in Three-Way Catalysts

The three way catalysts (TWCs) promoters (Ce Zr)O 2, (Pr Ce Zr)O 2 and (Pr Zr)O 2 were prepared by sol gel like method. They were characterized by XRD, EXAFS and BET surface area determination. The reduction features of the promoters were measured by temperature programmed reduction (TPR) of H 2 to access the potential for the promoters containing praseodymia as oxygen storage component in three way catalyst. The (Pr Zr)O 2 cubic solid solution is formed at high temperature up to 800 ℃, which makes it more reducible than the (Ce Zr)O 2 solid solution. For the (Pr Ce Zr)O 2 samples, the ternary solid solution plays an important role in the reduction process. The performance of the three way catalysts with fully formulated Pt, Pd and Rh is proceeded by using both light off temperature under a stoichiometric gas composition and the conversion of CO, C 3H 6 and NO under changing air/fuel ratio at a constant reaction temperature 400 ℃ . The results indicate that a small amount of praseodymia doping into (Ce Zr)O 2 favors the light off temperature of C 3H 6 and NO, and all the catalysts containing praseodymia obviously exhibits enhanced width of S value for NO conversion at lean region ( S ≥1.00).

CE3MN双相不锈钢铸件裂纹成因与预防

针对30″-300 Lb上装式球阀阀体用CE3MN铸造超级双相不锈钢材质,利用FactSage8.2热力学计算软件以及FSstel钢铁数据库,并结合光学显微镜、扫描电镜和能谱仪以及X射线衍射仪等试验手段,研究分析了CE3MN材质铸件在固溶处理之前切割铸态冒口时所产生的裂纹原因。结果表明:CE3MN铸件在脆性相析出的敏感温度范围以内缓慢加热或缓慢冷却过程中,由于铸造成分偏析严重而产生大量富Cr、Mo的有害金属间化合物σ相,主要以短棒状、细针状弥散分布于铁素体基体内或以长链状、条带状、珊瑚状、(σ+γ_(2))胞状以及魏氏组织长针状等形式分布于α/γ相界处。生产实践表明:在气割CE3MN铸件冒口之前,毛坯预先进行固溶处理以消除铸态脆性σ相,抑制裂纹形成和扩展,或者利用锯床先冷锯切铸态冒口后再进行固溶处理,可从根本上规避产生裂纹的温度因素。

湿法制备Cu基Mn-Ce改性甲醇重整制氢催化剂及其催化性能研究

为了提升Cu基催化剂的高温稳定性和使用寿命,并研究过渡金属Mn及轻稀土金属Ce对Cu基甲醇重整催化剂的影响,本文采用新型湿法制备了Cu基Mn-Ce改性催化剂,并在气-固相固定床催化反应装置上评价了其甲醇重整制氢的性能。甲醇转化实验结果显示,Cu基Mn-Ce改性催化剂的甲醇转化率达到98.77%,产出的(H2+CO)含量达到92.5%。高温碳化性能对比实验结果表明,相比未改性的催化剂,Mn-Ce改性催化剂的高温稳定性更强,使用寿命更长。高温碳化后,205℃下的甲醇转化率均在40%以上,未改性催化剂的转化率仅为20%左右。催化剂性能评价实验结果表明,催化反应温度与其制氢性能呈正相关,高温下催化剂有更优异的制氢表现。Mn、Ce的加入可以有效提高Cu基催化剂甲醇重整制氢的性能。

Improvement of Gold to Reducibility of La-Ce-Mn Catalyst under Lean Combustion

The effect of Au on the reducibility of La Ce Mn catalyst was studied in the synthetic exhaust gas mixture containing 10% oxygen. The characteristics of samples were analyzed by BET, SEM, XRD and activity evaluation. The results show that, in lean combustion, the performance of perovskite type catalysts is evidently enhanced through adding Au, and specially a satisfying reducibility for NO x is demonstrated between 300～500 ℃. The catalytic activity of samples increases with the loading amount of Au, and the maximum conversion rate for NO x decomposition reaches up to 47% in 360～400 ℃. Moreover, the dispersivity and uniformity of the surface distribution of perovskite with Au have an important influence on the catalytic activity.

Synthesis of multi-walled carbon nanotubes using CoMnMgO catalysts through catalytic chemical vapor deposition

The Co Mg O and Co Mn Mg O catalysts are prepared by a co-precipitation method and used as the catalysts for the synthesis of carbon nanotubes（CNTs） through the catalytic chemical vapor deposition（CCVD）. The effects of Mn addition on the carbon yield and structure are investigated. The catalysts are characterized by temperature programmed reduction（TPR） and X-ray diffraction（XRD） techniques, and the synthesized carbon materials are characterized by transmission electron microscopy（TEM） and thermo gravimetric analysis（TG）. TEM measurement indicates that the catalyst Co Mg O enclosed completely in the produced graphite layer results in the deactivation of the catalyst. TG results suggest that the Co Mn Mg O catalyst has a higher selectivity for CNTs than Co Mg O. Meanwhile, different diameters of CNTs are synthesized by Co Mn Mg O catalysts with various amounts of Co content, and the results show that the addition of Mn avoids forming the enclosed catalyst, prevents the formation of amorphous carbon, subsequently promotes the growth of CNTs, and the catalyst with decreased Co content is favorable for the synthesis of CNTs with a narrow diameter distribution.The Co Mn Mg O catalyst with 40% Co content has superior catalytic activity for the growth of carbon nanotubes.

Effect of Mn Promoter on Structure and Performance of K-Co-Mo Catalyst for Synthesis of Higher Alcohols from CO Hydrogenation

A series of Mn-doped K-Co-Mo catalysts were prepared by a sol-gel method. The catalyst structure was well characterized by X-ray diffraction, N2 physisorption, NH3 temperature- programmed adsorption, in situ diffuse reflectance infrared Fourier transform spectroscopy, and X-ray absorption fine structure spectroscopy. The catalytic performance for higher alcohol synthesis from syngas was measured. It was found that the Mn-doped catalysts ex- hibited a much higher activity as compared to the unpromoted catalyst, and in particular the C2＋ alcohol selectivity increased significantly. The distribution of alcohol products de- viated from the Anderson-Schulz-Flory law. The portion of methanol in total alcohol was suppressed remarkably and the ethanol became the predominant product. Characterization results indicated that the incorporation of Mn enhanced the interaction of Co and Mo and thus led to the formation of Co-Mo-O species, which was regarded as the active site for the alcohol synthesis. Secondly, the presence of Mn reduced the amount of strong acid sites significantly and meanwhile promoted the formation of weak acid sites, which had a positive effect on the synthesis of alcohol. Furthermore, it was found that the incorporation of Mn can enhance the adsorption of linear- and bridge-type CO significantly, which contributed to the formation of alcohol and growth of carbon chain and thus increased the selectivity to C2＋OH.

Mn基低温脱硝催化剂性能优化研究进展

氮氧化物(NO_(x))是我国首要大气污染物,主要采用选择性催化还原(SCR)技术进行排放控制.研发高效、稳定的低温脱硝催化剂可避免高能耗的烟气再热,具有显著的节能降碳效益.锰氧化物(MnO_(x))因多变的化学态和丰富的晶格缺陷而表现出优良的氧化还原性能,并具有极强的表面酸性,在催化还原NO_(x)反应中表现出良好的低温活性,但N_(2)选择性低、抗H_(2)O/SO_(2)性能差,难以实现长期的高效稳定脱硝.近年来,改性提升Mn基催化剂的研究十分广泛,加快了Mn基催化剂工业应用的步伐.本文从低温活性、N_(2)选择性和稳定性三个方面,总结了Mn基催化剂的脱硝反应机理、元素掺杂改性、催化剂结构设计等最新研究进展,指出了当前的研究重点和难点,可为下一步研究提供参考.

Modified Ceria-Zirconia Fluorite-Like Catalysts for the Combustion of Methane

For dispersed ceria-zirconia-based solid solutions prepared via the polymerized complex method and annealed at 700 ℃, effects of bulk doping by Ca, Mn, Co, Bi or Nb cations and surface modification by Mn and Pt on their structural features, surface/bulk oxygen reactivity and catalytic activity in methane combustion are considered. With up to 20 mol% doping, a structural type of homogeneous solid solutions of anion-deficient fluorite with disordered anion vacancies is formed. Doping by transition metal cations or Pt increases the mobility and reactivity of the surface/bulk oxygen. A broad variation in specific rates of methane combustion for the studied systems was observed, suggesting structural sensitivity of this reaction. In general, there is no universal relationship between the oxygen mobility, the reactivity and the catalytic activity in methane combustion, which is explained by the factor of specific methane activation on surface active sites. For the Pt-promoted samples, Pt efficiency in methane activation depends on the Pt-support interaction, and the most favorable ones being mixed Pt/MnOx and Pt/NbOx clusters on the surface of the supports that exhibit high lattice oxygen mobilities.

Influences of Platinum Precursors and Solution Acidities on REO-Based Catalysts Performances

Important effects exist between precious metals and rare earths oxides in three-way catalyst, especially the coordinated effects. These effects were studied by using H2PtCl6, Pt(NH3)2(NO2)2 and Pt(OH)2(C2H5ONH2)2 as Pt precursors, and the mixed oxide of (Ce-Zr-La-Pr)O as base material to prepare a series of catalysts, and their performances of the catalysts were studied by TPR and CO pulse titration technologies. The results shown that Pt precursors and their solutions pH values influenced the oxygen storage capabilities, the active metal distribution degrees of the catalysts obviously, and every catalyst prepared by different precursors had an optimal pH values. It indicates that the active metals precursors and their solutions acidities have outstanding influences on the catalysts performances for the mutual effects existing between the active metals and the Rare Earth metal oxides, which results from the mate groups of the precursors and the solution acidity.