Au@α-Fe_(2)O_(3)纳米棒的制备及光催化性能

本工作通过水热法与磁控溅射法结合成功构建了表面均匀沉积纳米Au粒子的α-Fe_(2)O_(3)(Au@α-Fe_(2)O_(3))纳米棒,纳米Au粒子的负载量和形态分别由磁控溅射时间和热处理温度调控。在沉积5.1%的纳米Au粒子后,因纳米Au的表面等离子体共振(SPR)效应,Au@α-Fe_(2)O_(3)纳米棒在550 nm处出现了一个新的吸收峰,其带隙由2.20 eV变窄至1.95 eV。Au@α-Fe_(2)O_(3)纳米棒的荧光强度和电化学阻抗显著降低,光电流从0.27μA·cm^(-2)增大至0.45μA·cm^(-2)。纳米Au粒子既拓宽了Au@α-Fe_(2)O_(3)纳米棒的可见光吸收性能,又抑制了电子-空穴对的复合。与α-Fe_(2)O_(3)纳米棒相比,Au@α-Fe_(2)O_(3)纳米棒的光催化性能变得更加稳定,Au@α-Fe_(2)O_(3)纳米棒的光催化效率提高约一倍。

Ca and Sr co-doping induced oxygen vacancies in 3DOM La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts for boosting low-temperature oxidative coupling of methane

It is urgent to develop catalysts with application potential for oxidative coupling of methane(OCM)at relatively lower temperature.Herein,three-dimensional ordered macro porous(3 DOM)La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)(A_(2)B_(2)O_(7)-type)catalysts with disordered defective cubic fluorite phased structure were successfully prepared by a colloidal crystal template method.3DOM structure promotes the accessibility of the gaseous reactants(O2and CH4)to the active sites.The co-doping of Ca and Sr ions in La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts improved the formation of oxygen vacancies,thereby leading to increased density of surface-active oxygen species(O_(2)^(-))for the activation of CH4and the formation of C2products(C2H6and C2H4).3DOM La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts exhibit high catalytic activity for OCM at low temperature.3DOM La1.7Sr0.3Ce1.7Ca0.3O7-δcatalyst with the highest density of O_(2)^(-)species exhibited the highest catalytic activity for low-temperature OCM,i.e.,its CH4conversion,selectivity and yield of C2products at 650℃are 32.2%,66.1%and 21.3%,respectively.The mechanism was proposed that the increase in surface oxygen vacancies induced by the co-doping of Ca and Sr ions boosts the key step of C-H bond breaking and C-C bond coupling in catalyzing low-temperature OCM.It is meaningful for the development of the low-temperature and high-efficient catalysts for OCM reaction in practical application.

纳米α-Fe_(2)O_(3)/壳聚糖修饰玻碳电极的电化学行为研究

通过不同温度煅烧获得不同比表面积的α-Fe_(2)O_(3)纳米颗粒,将纳米α-Fe_(2)O_(3)与壳聚糖制成复合材料。利用滴涂法,将纳米α-Fe_(2)O_(3)/壳聚糖复合材料修饰在玻碳电极上,并通过循环伏安法研究纳米α-Fe_(2)O_(3)/壳聚糖/玻碳电极对铁氰化钾电化学性能的影响。结果表明:随着烧结温度从280℃提高到700℃时,α-Fe_(2)O_(3)纳米颗粒的比表面积由136.5m^(2)/g变为2.1m^(2)/g。纳米α-Fe_(2)O_(3)/壳聚糖/玻碳电极能显著提高铁氰化钾的电化学性能,与裸电极相比,氧化和还原电流均显著提高,其电化学催化性能与其纳米α-Fe_(2)O_(3)比表面积密切相关,比表面积越大峰电流就越强。在最佳实验条件下,浓度在510^(-4)~510^(-3)mol/L范围内,铁氰化钾的还原电流与浓度呈良好的线性关系,检出限为1.25×10^(-5)mol/L,该修饰电极重复性和稳定性较好。

玻纤负载α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结薄膜的制备 及其催化性能

为了克服传统芬顿催化剂的降解速率慢、pH适用范围窄、难回收等缺点,采用浸涂溶胶-凝胶法制备了玻璃纤维负载的α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结薄膜(FCGF),对其结构、形态和化学组成进行表征,并将其用于亚甲基蓝的光芬顿催化降解,考察其催化活性、pH值适用性和重复使用稳定性。结果表明:CuFe2O4颗粒生长在α-Fe_(2)O_(3)颗粒表面,形成α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结;在模拟太阳光辐射条件下,加入2 g FCGF和20 mmol/L的H_(2)O_(2),50 mL质量浓度为30 mg/L的MB溶液在40 min后降解率达到97%,而在相同条件下加入α-Fe_(2)O_(3)与CuFe_(2)O_(4)降解率分别为20%和30%,其催化活性的增强可归因于异质结光催化剂产生的光诱导电位差驱动的光生载流子的有效分离;同时,FCGF在宽pH范围显示出较高活性,pH=10时,MB溶液40 min后降解效率仍达到63%;FCGF具有良好的稳定性,5次循环后其催化性能没有衰减,反应40 min后MB降解率仍可达97%。

Au/γ-Al_(2)O_(3)催化剂的绿色制备及其催化降解亚甲基蓝性能

利用侧柏叶提取液为还原剂制备了纳米金负载型Au/γ-Al_(2)O_(3)催化剂,研究了负载条件对金颗粒物理状态及催化剂比表面积的影响。利用XRD、BET、SEM、TEM对催化剂的晶型、孔结构和形貌进行表征,以亚甲基蓝作为目标污染物探究了Au/γ-Al_(2)O_(3)的催化降解能力。结果显示,最佳金负载率为1.00%,最佳煅烧温度为300℃。当Au/γ-Al_(2)O_(3)投加量为0.7 g·L^(-1)时,15 mL 0.5 g·L^(-1) NaBH_(4)能在10 min内降解97.67%的亚甲基蓝,且循环利用5次后单位质量催化剂的亚甲基蓝降解率不下降,说明Au/γ-Al_(2)O_(3)催化剂有良好的催化活性和稳定性。

基于生物质衍生α-Fe_(2)O_(3)的丙酮气体传感器实验研究

研制具有高灵敏度、低检测限的丙酮气体传感器对于工业生产安全和人体疾病诊断具有重要意义。本文以生物质脱脂棉为模板,采用金属盐溶液浸泡法和空气中煅烧处理相结合的策略制备了α-Fe_(2)O_(3)微米管,然后采用X射线衍射仪、热重分析仪、扫描电子显微镜(SEM)对α-Fe_(2)O_(3)的物相组成与表面形貌进行表征。所制备的α-Fe_(2)O_(3)传感器表现出优异的丙酮传感性能,包括高响应(192.51%@20×10^(-6)),低检测限(1×10^(-6)),优异的重复性和选择性,并分析传感器的敏感机制。该工作不仅为多孔金属氧化物材料的简便设计提供了方案,而且在构建用于高性能丙酮气体检测系统方面具有应用潜力。

ε-Fe_(2)O_(3)/FeO界面结构与相变机理研究

本文利用脉冲激光沉积技术在SrTiO_(3)(111)衬底上生长了ε-Fe_(2)O_(3)薄膜,并应用高分辨X射线衍射(HRXRD)、X射线光电子能谱(XPS)和透射电子显微镜(TEM)对薄膜的显微结构进行了系统表征。XRD和XPS的研究结果表明ε-Fe_(2)O_(3)(001)薄膜在SrTiO_(3)(111)衬底上外延生长,薄膜中Fe离子为+3价。TEM的结果表明,在TEM样品制备过程中,由于高能Ar离子束轰击,ε-Fe_(2)O_(3)/SrTiO_(3)界面上容易发生相变形成FeO。ε-Fe_(2)O_(3)/FeO/SrTiO_(3)的外延关系为ε-Fe_(2)O_(3)(001)[110]//FeO(111)[112]//SrTiO_(3)(111)[112]。基于ε-Fe_(2)O_(3)/FeO界面结构与取向关系,分析了离子束辐照诱导ε-Fe_(2)O_(3)→FeO相变的微观机制。

聚吡咯微胶囊γ-Fe_(2)O_(3)的合成及在膨胀阻燃环氧树脂中的应用

以聚吡咯(PPy)微胶囊γ-Fe_(2)O_(3)得到的PPy-Fe_(2)O_(3)为协效剂、二氨基二苯甲烷改性聚磷酸铵(DDP)为阻燃剂制备了膨胀阻燃环氧树脂(EP)复合材料。结合极限氧指数(LOI)、UL94、热重分析、锥形量热仪及扫描电镜探究PPy-Fe_(2)O_(3)对EP/DDP体系的阻燃性、热稳定性及成炭性能的影响。结果表明,PPy-Fe_(2)O_(3)的加入可增强EP/DDP体系的阻燃性能、抑烟性能及热稳定性。利用PPy-Fe_(2)O_(3)与DDP复配有助于形成更加致密和稳定的炭层结构以减少热释放和生烟量,其中添加0.2%PPy-Fe_(2)O_(3)与9.8%DDP可使EP复合材料的峰值热释放速率(PHRR)与峰值生烟速率(PSPR)分别下降12.3%与11.0%,并成功通过UL94 V-0级且具有35.5%的LOI值。热重分析表明,PPy-Fe_(2)O_(3)的加入显著提高了EP/DDP体系的热稳定性与成炭性能,其中含0.2%PPy-Fe_(2)O_(3)的EP复合材料在700℃时的残炭量达到32.0%。

4A分子筛负载Ce和γ-Fe_(2)O_(3)去除水中Sb(Ⅲ)和Sb(Ⅴ)的研究

为深度处理水中的三价锑[Sb(Ⅲ)]和五价锑[Sb(Ⅴ)],采用共沉淀法合成铈(Ce)、铁(γ-Fe_(2)O_(3))负载的4A分子筛新型吸附剂(4A@Ce-Fe)。Ce和γ-Fe_(2)O_(3)的负载显著提高了4A分子筛对锑的吸附能力,当铈铁质量比为1∶3、p H=7.0时,4A@Ce-Fe对Sb(Ⅲ)和Sb(Ⅴ)的最大吸附容量分别为50.50 mg/g和10.03 mg/g。4A@Ce-Fe的饱和磁化强度为23.70 emu/g,有良好的磁分离性能。Langmuir等温线模型可以更好地拟合Sb(Ⅲ)的吸附,而Langmuir和Freundlich两种等温线模型都能很好地拟合Sb(Ⅴ)的吸附。吸附动力学数据拟合表明,Sb(Ⅲ)和Sb(Ⅴ)的吸附更符合准二级动力学模型。4A@Ce-Fe在初始pH为4.0~10.0时有较好的吸附效果,Ce、Fe几乎没有溶出;共存Cl^(-)、SO_(4)^(2-)和NO_(3)^(-)对Sb(Ⅲ)和Sb(Ⅴ)的吸附效果影响较小,而共存HCO_(3)^(-)和H_(2)PO_(4)^(-)的影响则较大。XRD、SEM、BET、FTIR、XPS等测试结果表明,Sb(Ⅲ)和Sb(Ⅴ)在4A@Ce-Fe上可能的吸附机理包括离子交换、表面络合和氧化还原反应,其中M—O—Sb配合物的形成对Sb的吸附起主要作用。

无水草酸辅助硝酸铁热分解制备高饱和磁化强度γ-Fe_(2)O_(3)纳米粒子

采用硝酸铁和无水草酸为原料,通过简便的一步固相法焙烧制备γ-Fe_(2)O_(3)纳米粒子。采用XRD、SEM-EDS、N_(2)-吸附/脱附和VSM等表征手段分析了样品的结构、形态和磁性能。研究表明,在Fe(NO_(3))_(3)·9H_(2)O中添加C_(2)H_(2)O_(4),可以制备出饱和磁化强度为76.3 emu/g的棒状γ-Fe_(2)O_(3)。

α-Fe_(2)O_(3)纳米棒的水热合成与阻变开关特性研究

采用水热法合成了沿[110]方向具有优先生长取向的α-Fe_(2)O_(3)纳米棒,设计了具有非易失性阻变开关性能的W/α-Fe2O_(3)/FTO阻变存储器。对W/α-Fe_(2)O_(3/)FTO器件的阻变开关特性进行分析发现,W/α-Fe_(2)O_(3)/FTO阻变存储器的电阻比(RHRS/RLRS)在一个数量级以上,可保持100 s以上而无明显下降。此外,器件的载流子运输特性分别由LRS下的欧姆传导机制和HRS下的陷阱控制的空间电荷限制电流传导机制决定。由氧空位的迁移引起的纳米导电细丝的部分形成与断裂可以解释W/α-Fe_(2)O_(3)/FTO阻变存储器的非易失性阻变开关行为。因此,基于α-Fe_(2)O_(3)纳米棒的阻变存储器件可能是下一代非易失性存储应用的潜在候选器件。

α-Fe_(2)O_(3)@TiO_(2)纳米核壳球的制备及光催化清除乙烯性能研究

提高纳米TiO_(2)在可见光下光催化及乙烯清除效果。方法本文以FeCl_(3)·6H_(2)O和TiF4为原材料,采用水热合成法制备出以α-Fe_(2)O_(3)为核、以TiO_(2)为壳的纳米复合型材料α-Fe_(2)O_(3)@TiO_(2),通过X射线衍射、紫外可见漫反射吸收光谱及电子顺磁共振等光化学表征及乙烯清除实验,研究其光催化和乙烯清除能力。结果制备得到的α-Fe_(2)O_(3)粒子具有稳定的棒状结构,粒径长度为100~200 nm,宽度为50~100 nm;TiO_(2)粒子为分散均匀的锐钛型空心球,直径为100~200 nm;合成的α-Fe_(2)O_(3)@TiO_(2)纳米核壳球的禁带宽度降低到1.91 eV;DMPO-·O_(2)^(-)和DMPO-·OH的电子信号强度增大;具有优异的乙烯清除能力。结论本实验制备得到的α-Fe_(2)O_(3)@TiO_(2)纳米核壳球具有良好的光催化效果和乙烯清除能力,有望将其应用在果蔬保鲜中,实现杀菌、氧化分解有机物以及去除异味等功效,以达到延长货架期的目的。

具有交换各向异性的Fe_(3)O_(4)/α-Fe_(2)O_(3)核壳结构诱导的偏置现象

采用Fe_(3)O_(4)颗粒的固相氧化反应制备出Fe_(3)O_(4)/α-Fe_(2)O_(3)核壳结构颗粒,并在低于反铁磁奈尔温度(955 K)高磁场(1 T)下进行场冷却,对亚铁磁/反铁磁Fe_(3)O_(4)/α-Fe_(2)O_(3)核壳结构的晶体结构、微观形貌以及磁学性能进行了测试和分析。实验发现,随着亚铁磁Fe_(3)O_(4)表面反铁磁层α-Fe_(2)O_(3)厚度的增加,颗粒矫顽力从约57 Oe增大到4525 Oe,磁滞回线呈现出蜂腰状。当反铁磁层厚度约为533 nm时,核壳结构磁滞回线出现增强的交换偏置场~601 Oe。理论计算表明,由于亚铁磁性的Fe_(3)O_(4)和反铁磁性的α-Fe_(2)O_(3)界面处存在相互交换作用,当反铁磁厚度大于510 nm时,核壳结构各向异性能和塞曼能都高于界面交换能时,亚铁磁/反铁磁核壳体系会出现交换偏置的增强现象。

Non-thermal atmospheric-pressure positive pulsating corona discharge in degradation of textile dye Reactive Blue 19 enhanced by Bi_(2)O_(3) catalyst

In this work,monoclinic Bi_(2)O_(3) was applied for the first time,to the best of our knowledge,as a catalyst in the process of dye degradation by a non-thermal atmospheric-pressure positive pulsating corona discharge.The research focused on the interaction of the plasma-generated species and the catalyst,as well as the role of the catalyst in the degradation process.Plasma decomposition of the anthraquinone reactive dye Reactive Blue 19(RB 19) was performed in a selfmade reactor system.Bi_(2)O_(3) was prepared by electrodeposition followed by thermal treatment,and characterized by x-ray diffraction,scanning electron microscopy and energy-dispersive xray techniques.It was observed that the catalyst promoted decomposition of plasma-generated H_(2)O_(2) into ·OH radicals,the principal dye-degrading reagent,which further attacked the dye molecules.The catalyst improved the decolorization rate by 2.5 times,the energy yield by 93.4%and total organic carbon removal by 7.1%.Excitation of the catalyst mostly occurred through strikes by plasma-generated reactive ions and radical species from the air,accelerated by the electric field,as well as by fast electrons with an energy of up to 15 eV generated by the streamers reaching the liquid surface.These strikes transferred the energy to the catalyst and created the electrons and holes,which further reacted with H_(2)O_(2) and water,producing ·OH radicals.This was indentified as the primary role of the catalyst in this process.Decolorization reactions followed pseudo first-order kinetics.Production of H_(2)O_(2) and the dye degradation rate increased with increase in the input voltage.The optimal catalyst dose was 500 mg·dm^(-3).The decolorization rate was a little lower in river water compared with that in deionized water due to the side reactions of ·OH radicals with organic matter and inorganic ions dissolved in the river water.

Superwetting Ag/α-Fe_(2)O_(3) anchored mesh with enhanced photocatalytic and antibacterial activities for efficient water purification

Superwetting materials have drawn unprecedented attention in the treatment of oily wastewater due to their preferable anti-fouling property and selective oil/water separation.However,it is still a challenge to fabricate multifunctional and environmentally friendly materials,which can be stably applied to purify the actual complicated wastewater.Here,a Ag/Ag/α-Fe_(2)O_(3) heterostructure anchored copper mesh was intentionally synthesized using a facile two-step hydrothermal method.The resultant mesh with superhydrophilicity and underwater superoleophobicity was capable of separating various oil/water mixtures with superior separation efficiency and high permeationflux driven by gravity.Benefiting from the joint effects of the smaller band gap of Ag/α-Fe_(2)O_(3) heterojunction,inherent antibacterial capacity of Ag/α-Fe_(2)O_(3) and Ag nanoparticles,favorable conductive substrate,as well as the hierarchical structure with superwettability,such mesh presented remarkably enhanced degradation capability toward organic dyes under visible light irradiation and antibacterial activity against both Escherichia coli(E.coli)and Staphylococcus aureus(S.aureus)compared with the pure Ag/α-Fe_(2)O_(3) coated mesh.Impressively,the mesh exhibited bifunctional water purification performance,in which organic dyes were eliminated simultaneously from water during oil/water separation in onefiltration process.More importantly,this mesh behaved exceptional chemical resistance,mechanical stability and long-term reusability.Therefore,this material with multifunctional integration may hold promising potential for steady water purification in practice.

α-Fe_(2)O_(3)@SiO_(2)@Cu_(2)O核壳结构复合物的合成及其光催化性质的研究

采用水热法,以FeCl_(3)·6H_(2)O和NaH_(2)PO_(4)·2H2O为原料,制备了α-Fe_(2)O_(3)纳米颗粒,然后以TEOS作为硅源,CTAB作为造孔剂,制备α-Fe_(2)O_(3)包覆SiO_(2)的介孔材料,然后对SiO_(2)包覆的α-Fe_(2)O_(3)掺杂过渡金属Cu_(2)O,得到α-Fe_(2)O_(3)@SiO_(2)@Cu_(2)O核壳结构复合物,并且利用XRD对制备的产品进行表征,进行光催化活性的评价。结果表明,以高压汞灯为光源,亚甲基蓝浓度为15 mg/L,当催化剂用量为5 mg,90 min的降解率达到47.3%。

活性金属Ni d电荷密度对Ni_(2)P/Al_(2)O_(3)催化剂菲加氢性能的影响

高温煤焦油中菲含量高,将菲深度加氢饱和得到全氢菲,可提升菲利用率,且全氢菲密度大,热值高,可作为喷气燃料理想组分。然而,在菲加氢反应过程中菲与中间加氢产物的竞争吸附不利于菲在催化剂上吸附活化,且对称八氢菲进一步加氢是菲加氢饱和过程的速控步骤,其吸附活化困难不易解决,催化剂活性难以满足加氢需求。根据稠环芳烃与过渡金属间π络合吸附机理,在反应物吸附活化过程中,稠环芳烃分子和活性金属分别充当电子供体和电子受体,故Ni基催化剂中活性金属Ni处于缺电子状态时利于生成全氢菲,但关于Ni缺电子量及其电子结构如何影响催化剂菲、对称八氢菲加氢性能的原因需进一步探究。此外,基于负载型Ni_(2)P催化剂稳定性高、耐硫、耐氮性强等优势,采用次磷酸盐歧化法通过调变P/Ni物质的量比制备具有不同Ni d电荷密度的Ni2P/Al_(2)O_(3)催化剂,考察Ni d电荷密度对菲、对称八氢菲吸附和反应性能的影响规律。结果表明,在320℃、5 MPa、空速1 309 h-1反应条件下,Ni-2.5P/Al_(2)O_(3)催化剂转换频率fTO最高(44.64×10^(-3)s^(-1))。通过吸附活化熵描述菲、对称八氢菲与催化剂表面间相互作用强度,发现菲、对称八氢菲在不同Ni-xP/Al_(2)O_(3)催化剂表面吸附强度不同。通过定量计算Ni d电荷密度,明确了Ni2P/Al_(2)O_(3)催化剂用于菲加氢反应时适宜Ni d电荷密度约-0.24 e,对称八氢菲加氢反应适宜的Ni d电荷密度约-0.05 e。

基于层状锌铝复合氢氧化物前驱体优化制备Cu/ZnO/Al_(2)O_(3)气相醛加氢催化剂

以偏铝酸钠作为铝源通过一步法、两步法和混合法引入Cu制备基于ZnAl-LDH前驱体的3种不同的Cu/ZnO/Al_(2)O_(3)催化剂,对催化剂及其前驱体结构性质进行表征,结合辛烯醛(2-乙基-2-己烯醛,EPA)加氢反应评价结果,探究不同制备方法、不同铝的引入方式对ZnAl_(2)O_(4)尖晶石形成的影响,考察不同条件下所得催化剂的结构与反应性能之间的构效关系。结果表明:与工业催化剂相比,在辛烯醛气相加氢反应中混合法制得的催化剂与工业催化剂活性相当,产物选择性在空速1.5 h^(-1)时高于工业剂1.9%,在空速4.0 h^(-1)时高于工业剂2.5%;以偏铝酸钠作为铝源制备的ZnAl-LDH前驱物大大提高锌铝结合效率,减少非结合Al_(2)O_(3)的产生,提高产物选择性,同时实现380℃低温焙烧条件下ZnAl-LDH向ZnAl_(2)O_(4)尖晶石的转变,避免传统的高温焙烧过程中CuO的烧结。

络合剂对固相法Cu/ZnO/In_(2)O_(3)催化剂的CO_(2)加氢制甲醇反应性能的影响

为了促进催化剂中Cu物种的分散,在金属硝酸盐中分别加入草酸、甲酸和柠檬酸,采用固态研磨合成Cu/ZnO/In_(2)O_(3)催化剂.结果表明:草酸的加入对Cu的分散效果最好,在280℃,2 MPa,3.6 L·gcat^(-1)·h^(-1),V(H2)∶V(CO_(2))=3∶1时,甲醇收率最高,达到2.1 mmol·gcat^(-1)·h^(-1).但甲酸在高温下会分解为CO_(2)和H_(2),导致制备的CuO/ZnO/In_(2)O_(3)催化剂部分还原,随后此催化剂在H_(2)预处理后被过度还原,形成Cu_(3)In_(7)合金相,导致甲醇产率降低.

La_(1-x)Ce_(x)MnO_(3)-Ba/Al_(2)O_(3)催化剂对NO选择性生成NH_(3)的影响

为了实现碳中和目标,降低内燃机碳排放,稀薄燃烧技术成为了当前重要的研究方向.该技术不仅能提高发动机燃油热效率,还能有效降低CO_(2)排放.但是稀薄燃烧往往会伴随着大量氮氧化物的产生,为了解决该问题,采用LNT-SCR耦合的NO_(x)净化技术,此时LNT的作用是将排气中部分NO_(x)转化为NH_(3),为下游的SCR提供还原剂.基于此,制备了LNT催化剂,研究催化剂对NO选择性生成NH_(3)的影响.采用溶胶-凝胶法制备了La_(1-x)Ce_(x)MnO_(3)系列钙钛矿氧化物,并通过分步浸渍法得到了La_(1-x)Ce_(x)MnO_(3)-Ba/Al_(2)O_(3)负载型催化剂.利用XRD、H_(2)-TPR、NO-TPD等表征手段研究了钙钛矿氧化物的晶相结构,以及负载型催化剂的还原特性、NO_(x)吸附-脱附性能等物化性质,并且通过H_(2)选择性催化还原NO实验探究了催化剂掺杂Ce对NO转化成NH_(3)的影响.结果表明,Ce掺杂催化剂具有良好的NH_(3)产物选择性,并且显著提高了NO转化率.温度是NO转化和NH_(3)产物选择性生成的决定性因素,而H_(2)和NO体积比是NO转化和NH_(3)产物选择性生成的关键性因素.其中,La_(0.95)Ce_(0.05)MnO_(3)-Ba/Al_(2)O_(3)在低温下催化活性表现最佳,在350℃、H_(2)和NO体积比为5.0时NH_(3)产物选择性为65%,NO转化率为100%.此外,所制备的La_(1-x)Ce_(x)MnO_(3)都形成了钙钛矿型结构,而且Ce掺杂催化剂的大部分Ce离子可以进入到LaMnO_(3)结构中.在催化剂适量掺杂Ce后,H_(2)消耗总面积增大、还原峰的峰值温度降低,表明掺杂Ce改善了催化剂的还原特性;同时NO吸附和脱附面积增大,表明Ce掺杂改变了催化剂的NO_(x)吸附-脱附性能.