过渡金属掺杂对MnO_(x)-CeO_(2)低温SCR性能的影响

通过水解驱动氧化还原法合成了掺杂过渡金属的2Mn-Ce-M(M为Fe,Cu,Ni,Cr)催化剂,考察了过渡金属掺杂对低温SCR脱硝性能的影响.其中2Mn-Ce-0.2Cr催化剂比表面积较大,氧化还原能力适中,具有丰富的酸性位点和氧空位、最高的化学吸附氧含量及酸位强度,有利于低温下NH_(3)-SCR反应的顺利进行.2Mn-Ce-0.2Cr催化剂的低温NH_(3)-SCR活性最好,能在100~225℃的宽温度区间内保持80%以上的NO_(x)转化率,在125℃时NO_(x)转化率更是达到99.1%,为中低温催化还原烟气中的NO_(x)提供了新思路.此外,2Mn-Ce-0.2Cr还具有良好的抗硫抗水能力,在150℃下,加入40×10^(-6)的SO_(2)反应5 h,其催化活性稳定在98%;在3%的水蒸气下,其效率保持在95%以上.

喷涂法负载TiO_(2)/MnO_(2)陶瓷膜催化臭氧氧化降解染料废水

染料废水存在排放量大、色度高、COD大、可生化性差、难降解等特点,其处理存在低效高耗的问题.本研究首先通过水热法制备了TiO_(2)/MnO_(2)催化剂,对催化剂进行了XRD、XPS、SEM/EDS表征,以罗丹明B(RhB)溶液为模拟染料废水,进行了催化臭氧氧化降解RhB的性能对比研究.再通过喷涂成膜技术将TiO_(2)/MnO_(2)催化剂负载于平板式陶瓷膜表面,研制成反应性陶瓷膜(TiO_(2)/MnO_(2)-CM),自制了配套膜反应器,研究了TiO_(2)/MnO_(2)-CM水处理系统对RhB降解去除效果和水通量变化规律.结果表明,本工作成功合成了棒状和不规整球状结合的TiO_(2)/MnO_(2)催化剂,XPS结果表明存在Mn^(4+)活性中心,促进了催化臭氧活化能力.喷涂TiO_(2)/MnO_(2)催化剂后,陶瓷膜的纯水通量略有下降,12层为适宜的喷涂层数,采用TiO_(2)/MnO_(2)-CM对2 L初始浓度为20 mg·L^(−1)的RhB在臭氧浓度为2.5 g·m^(−3)条件下,反应40 min去除率可达100%,去除效率远高于空白膜,陶瓷膜负载TiO_(2)/MnO_(2)有助于提高O_(3)溶解性、加速生成·OH.本工作可为染料废水等难降解有机废水的高效低耗处理,提供新技术思路.

MnO_(2)负载贵金属催化剂用于CO低温催化氧化的研究

利用双氧水驱动促进贵金属沉淀的方法在MnO_(2)上负载贵金属制备了一系列Pd/MnO_(2)、Ru/MnO_(2)、Ag/MnO_(2)、Pt/MnO_(2)催化剂。通过对比贵金属负载型催化剂(负载量3.0%)催化氧化CO的活性,得到如下结果:3.0%Pd/MnO_(2)>3.0%Ru/MnO_(2)>MnO_(2)>3.0%Ag/MnO_(2)>3.0%Pt/MnO_(2)。为了探究催化剂活性与材料结构特性之间的关系,分别使用球差电镜、XRD、Raman、H_(2)-TPR、O_(2)-TPD和XPS等表征技术对催化剂表面贵金属的粒径尺寸、晶体结构、缺陷结构、低温还原性、活性氧物种以及金属元素价态分布等物理化学特性进行了系统的表征和分析。研究发现,负载了Ag或Pt的催化剂仅仅改善了MnO_(2)的低温还原性,由于在CO催化氧化过程中催化剂表面的贵金属被快速还原,因此催化活性有所下降。相反地,负载了Pd或Ru的MnO_(2)催化剂在CO氧化反应中的活性显著提高,这是材料良好的低温还原性与表面化学吸附氧物种之间的协同促进作用所致。由于3.0%Pd/MnO_(2)具有更好的低温还原性和更多的表面化学吸附氧物种,其能够在10℃条件下完全催化氧化CO气体(浓度为1%CO/4%O_(2),GHSV=40000 mL/(g·h))。通过分析不同催化氧化反应过程,推测Pd/MnO_(2)催化氧化CO遵循Langmuir-Hinshelwood(L-H)机理。

Ca_(2)MnO_(4)-layered perovskite modified by NaNO_(3)for chemical-looping oxidative dehydrogenation of ethane to ethylene

Chemical-looping oxidative dehydrogenation(CL-ODH)is a process designed for the conversion of alkanes into olefins through cyclic redox reactions,eliminating the need for gaseous O_(2).In this work,we investigated the use of Ca_(2)MnO_(4)-layered perovskites modified with NaNO_(3) dopants,serving as redox catalysts(also known as oxygen carriers),for the CL-ODH of ethane within a temperature range of 700-780℃.Our findings revealed that the incorporation of NaNO_(3) as a modifier significantly-nhanced the selectivity for-thylene generation from Ca_(2)MnO_(4).At 750℃and a gas hourly space velocity of 1300 h^(-1),we achieved an-thane conversion up to 68.17%,accompanied by a corresponding-thylene yield of 57.39%.X-ray photoelectron spectroscopy analysis unveiled that the doping NaNO_(3) onto Ca_(2)MnO_(4) not only played a role in reducing the oxidation state of Mn ions but also increased the lattice oxygen content of the redox catalyst.Furthermore,formation of NaNO_(3) shell on the surface of Ca_(2)MnO_(4) led to a reduction in the concentration of manganese sites and modulated the oxygen-releasing behavior in a step-wise manner.This modulation contributed significantly to the enhanced selectivity for ethylene of the NaNO_(3)-doped Ca_(2)MnO_(4) catalyst.These findings provide compelling evidence for the potential of Ca_(2)MnO_(4)-layered perovskites as promising redox catalysts in the context of CL-ODH reactions.

MnO_(2)-CeO_(2)纳米复合材料的制备及其对CO的净化催化性能

采用溶液燃烧法制备层状多孔结构MnO_(2)-CeO_(2)纳米复合材料。催化氧化实验表征产物结果表明,相较于纯CeO_(2),MnO_(2)-CeO_(2)纳米复合材料催化氧化CO性能明显提升:当复合材料(MnO_(2))所占百分比为30%时,CO的转化温度最低,有望成为低成本高性能的新型CO催化剂。

MnO_(x)-CeO_(2)催化剂的氯苯氧化性能及反应机理

研究了Mn/Ce摩尔比、反应温度、氧气和水对MnO_(x)-CeO_(2)催化剂催化氯苯氧化性能(活性、选择性和稳定性)的影响,并分析了其理化性能、作用过程和反应机理.结果表明,在含H_(2)Ogas和O_(2)(体积分数均为5%)条件下,Mn_(2)Ce_(1)O_(x)在100,200和300℃下分别取得了80.6%,86.8%和97.5%的氯苯转化率;反应温度和氧气含量的增加及水的存在均有利于提高催化活性和反应稳定性;MnO_(x)和CeO_(2)复合提高了比表面积(128.61 m^(2)/g)、降低了孔径(6.17 nm)且增强了表面酸性(中酸和强酸位点)和氧化还原能力,价态电子交互循环过程(Ce^(4+)/Ce^(3+)←→—Mn^(4+)/Mn^(3+)/Mn_(2)+)和氧循环作用(吸附氧←→—晶格氧)是催化反应的关键驱动过程.氯苯分子吸附在Mn_(2)Ce_(1)O_(x)催化剂表面发生脱氯反应形成苯酚,进一步开环氧化为关键的乙酸盐中间物种,最终转化为CO_(2),HCl或Cl_(2),H_(2)O.水和氧气可以活化为羟基和[O*]等活性氧物种,促进了氯苯的吸附活化和中间产物的深度氧化,降低了中间副产物(氯代乙氧基、苯酚和醛类等)的形成与表面Cl物种的沉积,进而提升了催化活性和反应稳定性.

MnO_(x)-CeO_(2)和Co_(3)O_(4)-CeO_(2)催化氧化甲醛的性能研究

采用水热合成法制备Ce-MOF载体,通过浸渍氧化锰、氧化钴的前驱体后得到催化剂MnO_(x)-CeO_(2)和Co_(3)O_(4)-CeO_(2)。研究表明,催化剂Co_(3)O_(4)-CeO_(2)在120℃时甲醛转化率为79.11%。MnO_(x)-CeO_(2)的催化性能最优,当温度为100℃时,可以将甲醛完全转化为H_(2)O和CO_(2)。通过X-射线衍射(XRD)、程序升温还原(H_(2)-TPR)和程序升温脱附(O_(2)-TPD)进行表征,说明加入Mn既有利于CeO_(2)表面氧物种的迁移,促进氧物种的脱附,又有利于表面氧在CeO_(2)的还原性,促进还原过程中的氧转移。结果表明,MnO_(x)-CeO_(2)低温时较强的还原能力以及其丰富的表面氧物种有利于提高催化剂的催化性能。

PPy对Al掺杂MnO_(2)电极材料电化学性能的影响

利用水热法制备Al 3+掺杂MnO_(2),再通过低温原位聚合法将其与聚吡咯(PPy)进行复合,制得了Al掺杂MnO_(2)/PPy复合电极材料,并对该复合材料进行了结构和形貌表征以及电化学性能测试.结果表明,Al掺杂MnO_(2)/PPy复合材料相比于Al掺杂MnO_(2)有更好的电化学性能.Al掺杂的MnO_(2)与PPy质量复合比为6∶1的电极(A0.45M6P1)在1 A/g的电流密度下比电容可达273.56 F/g,电流密度从1 A/g增加至10 A/g时比电容保持率为77.89%,在10 A/g下经过10000次循环后比电容保持率为93.2%.复合材料性能的改善主要归功于PPy为充放电过程中的电子提供了快速传输的路径,在MnO_(2)的纳米片上复合上一层PPy有利于缓解MnO_(2)在充放电过程中离子嵌入/脱出带来的体积效应.

Insights into effects of ZrO_(2) crystal phase on syngas‐to‐olefin conversion over ZnO/ZrO_(2) and SAPO‐34 composite catalysts

The utilization of metal oxide‐zeolite catalysts in the syngas‐to‐olefin reaction is a promising strategy for producing C_(2)–C_(4) olefins from non‐petroleum resources.However,the effect of the crystal phase of metal oxides on the catalytic activity of these oxides is still ambiguous.Herein,typical metal oxides(ZnO/ZrO_(2))with different crystal phases(monoclinic(m‐ZrO_(2))and tetragonal(t‐ZrO_(2)))were employed for syngas conversion.The(ZnO/m‐ZrO_(2)+SAPO‐34)composite catalyst exhibited 80.5%selectivity for C_(2)–C_(4) olefins at a CO conversion of 27.9%,where the results are superior to those(CO conversion of 16.4%and C_(2)–C_(4) olefin selectivity of 76.1%)obtained over(ZnO/t‐ZrO_(2)+SAPO‐34).The distinct differences are ascribed to the larger number of hydroxyl groups,Lewis acid sites,and oxygen defects in ZnO/m‐ZrO_(2) compared to ZnO/t‐ZrO_(2).These features result in the formation of more formate and methoxy intermediate species on the ZnO/m‐ZrO_(2) oxides during syngas conversion,followed by the formation of more light olefins over SAPO‐34.The present findings provide useful information for the design of highly efficient ZrO_(2)‐based catalysts for syngas conversion.

Photocatalytic activity and kinetics for acid yellow degradation over surface composites of TiO_2-coated activated carbon under different photocatalytic conditions

TiO2-coated activated carbon surface （TAs） composites were prepared by a sol-gel method with supercritical pretreatment. The photocatalytic degradation of acid yellow （AY） was investigated under UV radiation to estimate activity of catalysts and determine the kinetics. And the effects of parameters including the initial concentration of AY, light intensity and TiO2 content in catalysts were examined. The results indicate that TAs has a higher efficiency in decomposition of AY than P25, pure TiO2 particles as well as the mixture of TiO2 powder and active carbon. The photocatalytic degradation rate is found to follow the pseudo-first order kinetics with respect to the AY concentration. The new kinetic model fairly resembles the classic Langmuir-Hinshelwood equation, and the rate constant is proportional to the square root of the light intensity in a wide range. However, its absorption performance depends on the surface areas of catalysts. The model fits quite well with the experimental data and elucidates phenomena about the effects of the TiO2 content in TAs on the degradation rate.

PREPARATION,CHARACTERIZATION AND HYDROGENATION PROPERTY OF POLYMER-SUPPORTED Pd-Fe_2O_3 COMPOSITE CATALYSTS

A series of polymer- supported Pd -Fe2O3 composite catalysts were prepared and their hydrogenation property mas investigated. It was found that the above catalysts have good catalytic hydrogenation activity for carbon - carbon double bonds systems and reusability. Furthermore, XPS and IR spectra shouted that active component in the composite catalysts is atomic Pd(0). An addition of a small amount of Fe2O3 has a promotive action upon hydrogenation activity of the catalysts, which indicated that there are some strong interactions (electron transfer) between Pd(0) and Fe(Ⅲ) species. Based on these results, a possible catalytic hydrogenation mechanism was also suggested.

负载MnO_(2)纳米颗粒的可得然复合水凝胶的构建及其联合光热疗法对黑色素瘤B16-F10细胞的杀伤效果

目的:构建负载二氧化锰(MnO_(2))纳米颗粒的可得然(Cur)复合水凝胶MnO_(2)@Cur(简称MGel),研究其对黑色素瘤B16-F10细胞的杀伤效果。方法:采用热诱导法制备Cur水凝胶(Gel),物理负载MnO_(2)构建MGel,表征其宏观和微观形貌,检测其机械性能、降解性能以及光热转换性能等理化性能,并研究其联合PTT对小鼠皮肤黑色素瘤B16-F10细胞的光热杀伤效果。结果:MGel具有优异的机械和可降解性能,抗拉伸强度达(127.97±3.60)kPa、抗压缩强度达(151.44±5.23)kPa,28 d降解率约58.17%。MGel负载MnO_(2)纳米片(粒径约180 nm)获得优异的光热转换性能,负载1.0 mg/mL MnO_(2)的MGel在1.0 W/cm^(2)的808 nm NIR光照4 min后到达最高温度50℃。细胞毒性实验和Calcein-AM/PI荧光双染色实验表明,MGel联合PTT有效杀伤B16-F10黑色素瘤细胞,NIR光照使得MGel组细胞存活率降低至(4.68±0.66)%(P<0.0001)。结论:MGel复合水凝胶具备优异的机械性能、可降解性能以及光热转换性能,其联合PTT能有效杀伤肿瘤细胞,可能成为一种有效治疗黑色素瘤的新手段。

UiO-66-NH_(2)负载铜催化剂的制备及其对醇的催化氧化

通过溶剂热法成功制备了一种基于金属有机骨架(MOF)的复合材料Cu-Cu_(2)O/UiO-66-NH_(2),采用傅里叶变换红外光谱(FTIR)、X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)、X射线光电子能谱(XPS)对材料进行全面表征。在空气作氧化剂条件下,以苯甲醇氧化为苯甲醛作为模型反应,系统地考察了溶剂、温度、催化剂各组分用量等因素对催化效果的影响。研究结果表明,该复合催化剂在醇选择性氧化反应中表现出优异的催化性能,60℃下反应5 h便可将苯甲醇定量转化为苯甲醛,并对其他苄基醇、烯丙基醇和杂芳基醇等底物也展现出良好活性。此外,循环利用3次后,该催化剂活性几乎不变,表明其具有良好的稳定性和重复使用性。

Ru/α-MnO_(2)催化剂形貌对NH_(3)-SCO反应性能的影响

以具有不同形貌的线状(w)、管状(t)和棒状(r)的α-MnO_(2)为载体制备了Ru/α-MnO_(2)催化剂,考察了载体形貌对于氨选择性催化氧化(NH3-SCO)反应性能的影响,并利用多种手段表征了催化剂的物化性质、氧化还原性能和酸性。α-MnO_(2)形貌影响所暴露的晶面;线状、纳米棒和管状α-MnO_(2)分别暴露(110)、(310)和(200)晶面。Ru的引入提高了催化剂的耐水性能,其中管状Ru/α-MnO_(2)在水汽条件下NH3转化率为86%,N2的选择性为98%。Ru的引入对反应性能的影响与其对α-MnO_(2)表面酸性、氧化还原性能的影响密切相关。Ru降低了α-MnO_(2)-w表面酸量导致其活性下降;Ru对于α-MnO_(2)-r氧化性能的提高弥补了其导致的表面酸量的降低;而Ru对α-MnO_(2)-t氧化性和酸量的同时促进是Ru/α-MnO_(2)-t反应性能提升的主要原因。

Fe和Cu分子筛催化剂同时催化NO_(x)还原和N_(2)O分解

采用离子交换法制备了Fe-Beta和Cu-SSZ-13催化剂并采用不同混合方式制备了复合催化剂,考察了催化剂同时催化NO_(x)还原和N_(2)O分解的性能.以实现NO_(x)和N_(2)O同时高效去除、拓宽活性温度窗口为目标,优选出了上Fe下Cu分层填充、Fe-Beta和Cu-SSZ-13质量比为4:1的Fe_(0.4)Cu_(0.1)催化剂,进一步考察了进气组成对NO_(x)、N_(2)O和NH_(3)转化率的影响,并采用N_(2)吸脱附、XRD、NH_(3)-TPD、UV-Vis DRS和H_(2)-TPR等手段对催化剂理化特性进行了表征.结果表明,Cu-SSZ-13和Fe-Beta分别具有更优的催化NO_(x)还原和N_(2)O分解性能.采用Fe_(0.4)Cu_(0.1)催化剂、[NH_(3)]/[NO_(x)]为1时考察的温度范围内NH_(3)仅还原NO_(x),而N_(2)O通过分解去除,450℃时NO_(x)和N_(2)O转化率分别为93.4%和100%.高温(>350℃)下NH_(3)被O_(2)氧化导致NO_(x)转化率随温度升高而降低;高温(≥350℃)下N_(2)O分解形成的氧物种可使NO_(x)在进气中无O_(2)条件下实现高效还原.进气中含2%H_(2)O对高温(450℃)下Fe_(0.4)Cu_(0.1)表面NO_(x)的还原和NH_(3)的氧化无显著影响,但对N_(2)O的转化存在一定的可逆抑制作用.Cu-SSZ-13表面存在大量孤立的Cu^(2+)离子,可为NH_(3)-SCR反应提供充足的活性中心.Fe-Beta表面同时存在能够催化NO氧化的孤立Fe^(3+)离子和催化N_(2)O分解的Fe_(x)O_(y)物种.采用上Fe下Cu分层填充的混合方式时Fe-Beta表面NO氧化过程会消耗N_(2)O分解形成的氧物种,从而有利于低温(≤450℃)下N_(2)O的转化.但由于N_(2)O分解的温度范围内NO_(x)转化率本身较高,NO氧化对于脱硝的促进作用不显著.

MnO_(2)-CeO_(2)复合催化剂制备及室温下催化降解甲醛性能研究

本文采用络合法制备了MnO_(2)-CeO_(2)复合催化剂,用于室温下催化降解甲醛。通过正交实验确定了催化剂的最佳制备条件,通过连续催化降解甲醛实验考察了催化剂的催化稳定性。通过扫描电镜(SEM),X-射线能谱(EDS),X-射线衍射(XRD),N2吸附-脱附分析(BET)和氢气程序升温还原(H_(2)-TPR)对催化剂进行表征。结果表明,Mn/Ce摩尔比1∶1,水化热温度120℃,焙烧温度400℃,焙烧时间4h为催化剂的最佳制备条件,其中水化热温度为制备最关键的影响因素。MnO_(2)-CeO_(2)复合催化剂在室温下12h甲醛催化降解率为74.7%。连续催化降解甲醛实验中,降解率虽略有下降但仍在72%以上,催化剂的催化活性稳定。MnO_(2)-CeO_(2)复合催化剂是以MnO_(2)为主体的Mn-Ce-O混合氧化物,其表面形成以介孔为主的多孔表面,具有较大比表面积,在室温下对甲醛具有良好催化降解性能。

Hydrogen production performance of the non⁃platinum⁃based MoS_(2)/CuS cathode in microbial electrolytic cells

MoS_(2)/CuS composite catalysts were successfully synthesized using a one-step hydrothermal method with sodium molybdate dihydrate,thiourea,oxalic acid,and copper nitrate trihydrate as raw materials.The hydrogen pro-duction performance of MoS_(2)/CuS prepared with different molar ratios of Mo to Cu precursors(n_(Mo)∶n_(Cu))as cathodic catalysts was investigated in the two-chamber microbial electrolytic cell(MEC).X-ray diffraction(XRD),X-ray pho-toelectron spectroscopy(XPS),scanning electron microscopy(SEM),transmission electron microscope(TEM),linear scanning voltammetry(LSV),electrochemical impedance analysis(EIS),and cyclic voltammetry(CV)were used to characterize the synthesized catalysts for testing and analyzing the hydrogen-producing performance.The results showed that the hydrogen evolution performance of MoS_(2)/CuS-20%(nMo∶nCu=5∶1)was better than that of platinum(Pt)mesh,and the hydrogen production rate of MoS_(2)/CuS-20%as a cathode in MEC was(0.2031±0.0237)m^(3)_(H_(2))·m^(-3)·d^(-1) for 72 h at an applied voltage of 0.8 V,which was slightly higher than that of Pt mesh of(0.1886±0.0134)m^(3)_(H_(2))·m^(-3)·d^(-1).The addition of a certain amount of CuS not only regulates the electron transfer ability of MoS_(2) but also increases the density of active sites.

CeO_(2)/BiOBr/CNTs催化剂的制备及其降解抗生素性能研究

采用水热法合成了CeO_(2)、CeO_(2)/BiOBr、CeO_(2)/CNTs和CeO_(2)/BiOBr/CNTs复合纳米材料催化剂,利用XRD、SEM、BET和UV-Vis等方法对材料的结构、形貌和织构特性进行表征。在长弧氙灯照射下模拟太阳可见光降解抗生素,研究复合纳米材料的光催化氧化性能。结果表明,CeO_(2)与BiOBr、CNTs间的协同作用导致其对土霉素降解效果优于CeO_(2);CeO_(2)/BiOBr/CNTs对抗生素和可见光具有更高的吸收性能,比CeO_(2)/BiOBr和CeO_(2)/CNTs有更高的降解效率。在弱碱性环境下生成活性基团·OH,复合材料催化效果较好。复合材料禁带宽度都在可见光范围内,CeO_(2)的复合提高了材料的光利用效率,增强了材料的吸附性和电子-空穴对的迁移效率,进而提高其光催化活性。回收脱附实验表明,CeO_(2)/BiOBr/CNTs复合材料具有较好的稳定性。

水热法合成催化氧化高含硫废水的Ni-MnO_(2)/Al_(2)O_(3)制备条件优化

针对油气田高含硫废水快速氧化处理的需求,以Ni为金属助剂,MnO_(2)为活性组分,采用水热法制备了Ni-MnO_(2)/Al_(2)O_(3)催化剂,通过对高含硫废水催化氧化性能的研究优化了Ni-MnO_(2)/Al_(2)O_(3)的制备条件。BET、XPS、SEM表征结果表明,Ni与Mn摩尔比对催化剂的比表面积变化影响最大,摩尔比为2:10时催化剂的比表面积最大为232.5 m^(2)/g,吸附氧和晶格氧的比例高达2.02;水热温度影响催化剂的形貌,低温时以棒状结构为主,110℃时形成有序的片状结构,过高的温度会引起晶粒的团聚;较大的比表面积、丰富的多孔结构及高的吸附氧是催化活性高的主要原因。因此,在Ni与Mn摩尔比为2:10、水热温度为110℃、水热时间为12 h、焙烧温度为400℃的条件下制备的Ni-MnO_(2)/Al_(2)O_(3)催化剂具有最高的催化活性,对于硫离子浓度为3000 mg/L的废水,90 min后的硫离子转化率高达96.6%,对含硫废水的处理效果最好。

Nb_(2)O_(5)/Nb_(2)C催化剂的制备及其光催化NO转化的性能

采用焙烧法原位构建Nb_(2)O_(5)/Nb_(2)C异质样品,通过XRD、Raman、SEM、BET、UV-Vis DRS、MottSchottky及EIS等技术对样品的结构及性质进行分析,以NO为目标污染物评价其光催化活性。结果表明:Nb_(2)O_(5)/Nb_(2)C异质样品能够提供较多的反应活性位点、提高光的利用率及光生电子和空穴的分离效率,进而提高其光催化活性;在模拟太阳光照射下,其对NO的转化率达到了50.5%,分别为Nb_(2)O_(5)和Nb_(2)C样品的2.4倍和14.4倍,且在NO转化过程中,NO_(2)选择性转化率仅为0.75%。