Y2SiO5:Ce3+荧光体的基质多面体替换及其对发光性能的调控研究

荧光材料基质的结构调制对于调控发光材料的发光性能,探索固体结构-性能关系具有重要的研究意义。本文以Y2SiO5基质为模型,分别利用Si/Al和Si/P取代,以[AlO4]和[PO4]四面体替换[SiO4]四面体,设计合成了一系列组成为Y1.95Si1-xAlxO5-xFx∶0.05Ce3+(x=0.05,x=0.1,x=0.2,x=0.4,x=1)和Y1.95-yCaySi1-yPyO5∶0.05Ce3+(y=0,y=0.02,y=0.04,y=0.06,y=0.08,y=0.2)的荧光材料。结合X射线衍射、荧光光谱、荧光寿命等测试手段对其进行了表征分析。结果表明,在x≤0.2,y≤0.04时得到的产物能够保持Y2SiO5的结构特征,在一定的基质组成替换范围内,设计合成的样品Y1.95Si1-xAlxO5-xFx∶0.05Ce3+、Y1.95-yCaySi1-yPyO5∶0.05Ce3+能提高发光强度,发射光谱呈现蓝移现象。荧光寿命测试表明这两个系列的化合物中Ce3+所处的基质环境变化较小,Ce3+发光也未产生较大的变化。     

锆含量对（CeMn）1-xZrxO2催化剂催化燃烧碳烟稳定性能的影响

采用共沉淀法制备了系列(CeMn)1-xZrxO2[n(CeO2)∶n(MnO2)=6∶4,0≤x≤0.3]催化剂并进行了表征.考察了该系列催化剂对柴油车排放碳烟的催化燃烧性能.X射线衍射和低温氮气吸附-脱附结果表明,向CeMnO2催化剂中引入ZrO2后可以有效稳定催化剂的结构性能和织构性能,当x≥0.2时对结构性能的稳定效果最佳,当x≥0.1时对织构性能稳定效果最佳.氢气-程序升温还原(H2-TPR)结果表明,加入ZrO2后稳定了老化催化剂的低温还原性能,当x=0.2时老化催化剂的低温还原性能最优.氧气-程序升温脱附(O2-TPD)结果表明,加入ZrO2后增加了催化剂表面的阴离子空位,使其吸附和活化氧的能力增强.活性测试结果表明,该系列新鲜催化剂用于碳烟的催化燃烧可有效降低碳烟在燃烧过程中失重速率最大时对应的温度(Tm)约270℃,老化后引入锆的催化剂的稳定性能明显优于无锆催化剂,当x=0.2时催化剂的抗老化性能最佳,于700℃老化20 h前后Tm的差仅有6℃.     

SO2对La0.8K0.2Cu0.05Mn0.95O3钙钛矿催化剂氧化碳烟的影响

采用柠檬酸配位法制备K、Cu掺杂的Lu0.8K0.2Cu0.05Mn0.95O3钙钛矿催化剂,运用程序升温氧化(TPO)考察在不同浓度SO2气氛下La0.8K0.2Cu0.05Mn0.95O3催化剂催化氧化模拟碳黑的性能,并用XRD、FFIR和XPS等进行表征.结果表明,催化剂在0～0.1%的SO2气氛中呈现出不同活性,φSO2≤0.05%的气氛可促进催化剂催化氧化碳黑的活性,当φSO2=0303%,催化剂活性最高;引入φSO2≥0.06%时催化剂活性明显下降.XPS说明表面活性氧的增加是低浓度的SO2促进催化活性的原因,同时XRD、FTIR结果表明高浓度的SO2所产生的大量SO42-是抑制催化剂活性的原因.     

Ni-Fe/La2O2CO3催化乙醇水蒸气重整制氢的研究

采用La2(CO3)3空气焙烧法制备了La2O2CO3载体、采用浸渍法制备了Ni,Fe不同比例的Ni-Fe双金属催化剂及Ni/La2O2CO3,Fe/La2 O2 CO3催化剂,考察了各催化剂从300～700℃催化乙醇水蒸气重整反应的性能,并用BET,XRD,TPR等技术对催化剂进行表征。结果表明,相对单一金属催化剂,Ni-Fe双金属催化剂均表现出更高的活性,这可能是因为高分散的Ni,Fe和LaFeyNi1-yO3的共存作用。其中Ni含量为10%,Fe含量为5%时的Ni-Fe/La2O2CO3表现出最高的活性,400℃时乙醇的转化率为100%,H2的选择性最高达到94.1%,而CO的选择性则低至1.2%。     

NiCe(x)/FLRC-TiO2催化剂的制备及其加氢脱氧性能研究

生物质作为自然界唯一可再生的有机碳源,其转化利用具有重要意义.本工作制备了具有特殊形貌和孔道结构的放射状二氧化钛(FLRC-TiO₂)载体,并在高加氢活性Ni基础上,引入Ce赋予催化剂酸活性位,制备了负载型金属-酸双功能NiCe(x)/FLRC-TiO₂催化剂(x为Ni和Ce的原子比),并以对甲酚为模型化合物,研究了Ni/Ce比对催化剂加氢脱氧(HDO)性能的影响.结果表明,Ce的引入能够增强催化剂的酸性,增强催化剂C—OH键氢解能力,从而提高甲基环己烷(MCH)选择性.与单金属Ni/FLRC-TiO₂相比,双金属NiCe(1)/FLRC-TiO₂的目标产物MCH的选择性显著提高.在275℃、3 MPa、2.5 h的反应条件下, NiCe(1)/FLRC-TiO₂催化剂对对甲酚转化率为100%,脱氧产物选择性为97.9%,且MCH的选择性高达95.4%. NiCe(1)/FLRC-TiO₂催化剂上的HDO以hydrogenation (HYD)反应路径为主...     

CexTi1-xO2负载锰基催化剂的制备及其低温NH3选择催化还原NO

用共沉淀法制备了CexTi1-xO2复合氧化物载体。XRD和低温N2吸附-脱附结果指出,当0.2≤x≤0.4时,CexTi1-xO2载体主要以无定形态存在,且Ce0.4Ti0.6O2的比表面积和孔容最大。Mn-Fe/CexTi1-xO2系列催化剂低温NH3选择性催化还原(SCR)NO活性结果表明,Mn-Fe/CexTi1-xO2的活性随着Ce含量的增加先增大后减小,其中Mn-Fe/Ce0.4Ti0.6O2的活性最佳,在41000 h-1空速下,催化剂在75℃起燃,NO转化率在113℃时即超过90%。而XRD和XPS分析结果指出,Mn-Fe/Ce0.4Ti0.6O2催化剂主要以无定形或微晶的形式存在,催化剂表面Mn和Fe与载体间存在强相互作用,且催化剂表面存在Ce3+/Ce4+氧化还原电对和较多的化学吸附氧,有利于NO氧化成NO2,同时催化剂表现出了较好的抗H2O和SO2性能。     

制备方法对Ni/CeO2-Al2O3催化剂甲烷部分氧化催化性能的影响

采用浸渍-沉淀法、水热合成法、共沉淀法和柠檬酸络合法制备了Ni/CeO₂-Al₂O₃催化剂,考察了制备方法对该催化剂的物理结构和甲烷部分氧化(POM)催化性能的影响。利用N₂物理吸附、X射线粉末衍射(XRD)、H₂-程序升温还原(H₂-TPR)、NH₃-程序升温脱附(NH₃-TPD)、热重(TG)分析等手段对反应前后催化剂的物理化学性质进行了表征。实验结果表明,浸渍-沉淀法制备催化剂的活性和产物H₂和CO的选择性最低。而柠檬酸络合法制备的Ni/CeO₂-Al₂O₃表现出最大的CH₄转化率和最高的CO、H₂选择性。BET和XRD表征结果表明,柠檬酸络合法制备的Ni/CeO₂-Al₂O₃的比表面积最大,且CeO₂晶粒粒径小、分散均匀;H₂-TPR测试表明,该催化剂负载的Ni物种和Ni与Al₂O₃相互作用产生的尖晶石NiAl₂O₄都较容易被还原成金属Ni,产生更多的活性中心;NH₃-TPD和TG分析表明,该催化剂具有较多酸性位点和表面积炭,但相比较于它的高反应活性,积炭速率较低、稳定性较高。     

等离子体技术对CO2甲烷化用Ni/SiO2催化剂的改性作用

采用浸渍法制备了Ni/SiO₂催化剂,应用等离子体技术对催化剂进行改性处理。以CO₂甲烷化为模型反应对催化剂进行活性评价,通过H₂程序升温还原(H₂-TPR)和CO₂程序升温脱附(CO₂-TPD)技术对催化剂进行表征。研究了等离子体技术强化处理对催化剂吸附性能和还原性能的影响。结果表明,与常规焙烧的催化剂相比,等离子体技术改性处理提高了催化剂活性组分的分散度,增加反应活性位并调变了活性位对吸附物种的吸附强度,改进了催化剂的还原性能,CO₂甲烷化反应活性和甲烷的时空产率显著提高。     

反相微乳法制备Ni/CeO2纳米复合催化剂催化乙醇水蒸气重整制氢

采用W/O反相微乳法制备了Ni/CeO2纳米复合催化剂,对比了加热和真空冷冻两种不同干燥方法处理的催化剂以及传统浸渍法制备的催化剂上乙醇水蒸气重整反应性能。由X射线衍射(XRD)、透射电子显微镜(TEM)、程序升温还原(TPR)和程序升温脱附(TPD)等技术对催化剂进行了表征。实验结果表明,采用反相微乳法制备的Ni/CeO2纳米复合催化剂显示了良好的催化活性和选择性;其中采用真空冷冻干燥处理的催化剂表现出最好的活性,H2产率最高达到42%,CO选择性低至0.35%,并且具有较好的稳定性和抗积炭能力,优于传统浸渍法制备的催化剂。     

Ni/γ-Al2O3催化剂的2-MF气相加氢合成2-MTHF性能研究

2-甲基四氢呋喃(2-MTHF)是极具市场潜力的生物燃料、绿色溶剂和化学中间体.采用浸渍法制备Ni/γ-Al2O3催化剂,在固定床反应器评价其2-甲基呋喃(2-MF)气相加氢合成2-甲基四氢呋喃(2-MTHF)反应性能.通过XRD、N2等温吸附-脱附、H2-TPR、NH3-TPD、TEM、H2吸附和XPS对催化剂结构和表面性质进行表征,研究Ni负载量、焙烧温度和反应条件对催化剂性能的影响规律.结果表明:Ni/γ-Al2O3催化剂的Ni金属面积、晶粒尺寸、反应温度和压力都会影响2-MF的转化率;孔结构、酸量和反应温度是影响2-MTHF选择性的主要原因,平均孔径大、酸量大和适宜的反应温度有利于提高2-MTHF选择性. 400℃焙烧的负载量为15%的Ni/γ-Al2O3催化剂, Ni金属面积大、晶粒尺寸小、总酸量多,催化剂表面的金属活性中心与酸性中心协同作用促进了2-MF呋喃环上C=C加氢生成2-MTHF,性能较优.在2 MPa、100℃、WHSV=2.7 h-1、H2/2-MF=6.4的条件下,该催化剂上2-MF转化率为99.8%, 2-MTHF选择性为98.0%,催化剂可以稳定运行40 h.     

La2O3对Ni/γ-Al2O3甲烷化催化剂的助催化作用

我国将稀土作为助剂引入镍基甲烷化催化剂,大大提高了催化剂的活性和热稳定性,并已投入工业应用［1－3］．稀土对不同镍催化剂反应性能及其作用机理的研究已有一些报导［3－7］．谢有畅等观察到镍负载在经单层La2O3改性的γ－Al2O3表面,其晶粒要比没有La2O3时小得多．Rotgerink等认为添加La后反应速率的增加不只是由于几何效应,而是La对甲烷化本身有促进作用,单位镍表面的活性是随La含量不同而改变的,活性增加的同时表观活化能也增加［5］．作为助剂的La2O3在氢还原和反应过程中的变化及其作用的研究和讨论较少,目前一般认为添…     

A bifunctional perovskite oxide catalyst:The triggered oxygen reduction/evolution electrocatalysis by moderated Mn-Ni co-doping

ABO₃-type perovskite oxides(e.g.,LaCoO₃)with flexible and adjustable A-and B-sites are ideal model catalysts to unravel the relationship between the electronic structure and electrocatalytic activity(e.g.,oxygen reduction/evolution reactions,ORR/OER).It has been well understood in our recent work that the secondary metal dopant at B-site(e.g.,Mn in LaMn_xCo_1-xO₃)can regulate the electronic structure and improve the ORR/OER activity.In this work,the Mn-Ni pairs are employed as the dual dopant in LaMn_xNi_yCo_zO₃(x+y+z=1)catalysts toward bifunctional ORR and OER.The structure-property relationships between the triple metal B-site(Mn,Ni and Co)and the electrochemical performance are particularly investigated.Compared to the individual Mn doping(e.g.,LaMnCoO3(Mn:Co=1:3)catalyst),the dual Mn-Ni doping significantly improves the ORR mass activity@0.8 V by 1.54 times;meanwhile,the OER overpotential@10 mA cm^-2 is reduced from 420 to 370 mV,and the OER current density at 1.55 V is increased by 2.43 times.Reasonably,the potential gap between EDRR@-1 mA cm^-2 and EDER@10 mA cm^-2 is achieved as only 0.76 V by using the optimal LaMn_xNi_yCo_zO₃(x:y:z=1:2:3)catalyst.It is revealed that the dual Mn-Ni dopant efficiently optimizes electron structures of the LaMnNiCoO₃(1:2:3)catalyst,which not only decreases the e_g orbital electron number,but also modulates the O 2 p-band closer to the Femi level,accounting for the enhanced bifunctional activity.     

Ni/Al2O3催化甲烷裂解

分别通过浸渍法和共沉淀法制备了不同Ni负载量的Ni/Al2O3催化剂。考察了Ni负载量、制备方法以及反应温度对Ni/Al2O3催化甲烷裂解性能的影响。结果表明,在550℃,浸渍法制备的Ni/Al2O3催化剂,当Ni负载量为20%(质量分数)、Ni金属平均粒径为11.25 nm时,具有最佳的甲烷催化裂解效果,其每摩尔Ni的氢气产量和每克Ni碳产量分别为164 mol和15.30 g。催化剂制备方法对Ni/Al2O3甲烷催化裂解反应有显著影响,相同Ni负载量共沉淀法制备的Ni/Al2O3甲烷催化裂解总体效果要好于浸渍法制备的Ni/Al2O3,而且反应过程中生成的碳纤维较长,管径也较均一。550℃时,共沉淀法制备的Ni负载量为41.2%(质量分数)的Ni/Al2O3催化剂在反应至350 min时,仍保持着30%以上的转化率。     

Effect of electron beam irradiation on CO2 reforming of methane over Ni/Al2O3 catalysts

The effect of electron beam irradiation on the CO₂ reforming of methane over Ni/Al₂O₃ was investigated. The conversion rate of CO₂ and CH₄ forming H₂ and CO using various catalysts irradiated with an absorbed dose greater than 2 MGy was 5–10% higher than when using an untreated catalyst. The Ni/O ratio on the catalyst surface increased after treatment with an electron beam, and was more prominent for catalysts with a higher Ni content. As such, based on XRD and XPS measurements, electron beam treatment was found to result in either the desorption of oxygen from NiO or the removal of OH groups from the outermost surface layer of the catalyst. In addition, the concentration of active sites, such as Ni²⁺ and NiO, or surface defects was also found to increase with the absorbed radiation dose, thereby increasing the conversion rate.     

低浓度甲烷甲醇深度氧化Ag/La0.6Sr0.4MnO3催化剂

Ag-modified La0.6Sr0.4MnO3 catalysts were prepared and their catalytic performance for deep oxidation of CH4 and CH3OH at low concentrations were investigated. The results showed that the La0.6Sr0.4MnO3 host catalyst with the perovskite-type nano-crystallite structure displayed considerably high catalytic activity for deep oxidation of CH4 and CH3OH at low concentrations. Ag modification to the La0.6Sr0.4MnO3 host catalyst resulted in significant enhancement of the catalyst activity, making the T95 (the reaction temperature needed for conversion of 95%of CH4 or CH3OH) lowered down to 735K (for CH4) and 421K (for CH3OH) from 813 and 465 K over the Ag-free system under the reaction conditions:0.1MPa,CH4/O2/N2=2/12/86(molar ratio),GHSV=45000 h-1 and CH3OH/O2/N2= 0.2/1.0/98.8 (molar ratio),GHSV=58000 h-1,respectively.The carbon containing product was almost CO2 and the contents of HCHO and CO in the reaction exit gas were both under GC detectable limit in both cases.
The results of spectroscopic characterization indicated that modification by proper amount of Ag-dopant did not change the perovskite structure of the La0.6Sr0.4MnO3 host catalyst as a whole. Interaction of Ag-dopant with the surface of the host catalyst,La0.6Sr0.4MnO3,was in favor of high dispersion of the Ag component at the catalyst surface and led to the oxidation of part of the Mn3+species to Mn4+,resulting in an increase of amounts of the reducible Mnn+ species and a decrease of their reduction temperature. On the other hand, this interaction led also to enhancement of adsorption ability of the catalyst toward O2 at relatively low temperature. High activity of the Ag modified La0.6Sr0.4MnO3 catalyst for CH4 and CH3OH complete oxidation was closely related to high redox-activity of the catalyst and its prominent adsorption-activation ability to O2 at relatively low temperatures.     

氮气气氛下焙烧的CeO_2载体负载Ni基催化剂的顺酐加氢性能研究

在氮气气氛中合成了具有较高氧缺陷浓度的CeO_2载体,采用浸渍法制备了Ni含量为10%的Ni/CeO_2-N催化剂,考察了其顺酐液相加氢性能,并与氧气气氛中制得的CeO_2载体负载Ni催化剂作了对比.N_2低温物理吸脱附,X-射线衍射,拉曼光谱,H_2程序升温还原等表征手段表明,在氮气气氛中合成的CeO_2具有较高浓度的氧缺陷位,在催化剂还原过程中可促进NiO物种的还原,同时在催化剂表面生成更多的氧缺陷位.该氧缺陷位可与活性金属Ni物种协同作用,显著提高催化剂的C=C及C=O加氢活性.     

层状钙钛矿型Sm2-2xSr1+2x-2yCa2yMn2O7(x=0.2，0.3，0.4，0.5；y=0，0.2，0.3)的溶胶凝胶合成及电性能研究

Layered perovskite manganites with a nominal chemsitry of Sm_2-2xSr_1+2x-2_yCa_2yMn₂O₇(x=0.2, 0.3, 0.4, 0.5; y=0, 0.2, 0.3) were prepared using sol-gel method. The crystal structures of these compounds were studied by X-ray diffraction (XRD) and FTIR absorption spectra. The absorption peaks become weaker and move a little to higher frequency with increasing of Sm/Sr concentration. As the Sm doping increases to x=0.2 and x=0.3, the absorption peaks show a cubic structure character, reflecting that the samples suffer from a transition from tetragonal structure to cubic structure. This coincides with the X-ray diffraction results. The high temperature electrical properties were studied by conventional four-probe method. Although all samples exhibit the semiconductive behavior, lnρ-1 000/T curves are not linear and they obey the small polaron hopping mechanism. Moreover, the resistivity decreases with x reducing. This is due to that Sm doping increases the Jahn-Teller ion Mn³⁺/Mn⁴⁺ ratio, and decreases the e_g bandwidth.     

氧化铝载体硫酸化对锰铈催化剂SCR脱硝性能的影响

分别以硫酸改性前后的氧化铝为载体,采用浸渍法制备了锰铈催化剂,对其NH_3-SCR脱硝性能进行评价,并采用XRD、BET、NH_3-TPD、H_2-TPR以及FT-IR对催化剂进行了表征。结果表明,改性降低了金属的分散性和氧化性,增加了酸量,特别是B酸量;催化剂的最佳脱硝温度窗口向高温扩展,活性温度窗口范围变宽,并且,改性液浓度越大变化幅度越大。当反应温度在200-250℃时,未改性催化剂与采用0.2 mol/L硫酸改性的催化剂具有接近的催化活性,但改性后的催化剂具有更高的抗水抗硫活性,250℃时脱硝率可达70%。     

二甲基二硫醚对Ni/Al_2O_3催化剂加氢性能的影响

考察了二甲基二硫醚(CH3SSCH3)对Ni/Al2O3催化剂上苯、环己烯和苯乙烯加氢活性的影响,并采用BET、XRD、H2-TPR、XPS、SEM和EA等手段对催化剂进行表征。实验结果表明,在CH3SSCH3存在下,Ni/Al2O3催化剂对苯和环己烯加氢迅速失活,且环己烯加氢对CH3SSCH3的耐硫性要略强于苯加氢,而苯乙烯中共轭烯烃的加氢转化率则维持100%长时间不变。CH3SSCH3的影响顺序为芳环单烯烃共轭烯烃。此外,通过设计实验研究了CH3SSCH3对催化剂的毒化机理,发现CH3SSCH3分子首先吸附在催化剂的表面,并发生氢解生成甲烷随尾气逸出,故CH3SSCH3分子中碳对催化剂的失活影响较小,而留下的硫原子则与镍活性组分发生相互作用,毒化催化剂。