结构钢电沉积Co-W/CeO_(2)复合镀层及其性能研究

选择CeO_(2)颗粒作为复合相,利用电沉积技术在普通结构钢表面制备出Co-W/CeO_(2)复合镀层,并研究镀液中CeO_(2)颗粒浓度对复合镀层的微观形貌、化学成分、结合力、硬度、耐磨性能以及高温抗氧化性能的影响。结果表明:Co-W/CeO_(2)复合镀层与基体结合牢固,表面分布着类似胞状的晶粒团聚体,其化学成分为Co、W、Ce和O元素。随着镀液中CeO_(2)颗粒浓度从2 g/L升高到15 g/L,复合镀层的晶粒团聚体尺寸差异先减小后增大,吸附在晶粒团聚体表面及边界处的CeO_(2)颗粒量先增多后减少,导致复合镀层的硬度、耐磨性能和高温抗氧化性能都呈先增强后下降的趋势。当镀液中CeO_(2)颗粒浓度为8g/L时,Co-W/CeO_(2)复合镀层的晶粒团聚体大小较为均匀,具有良好的致密性,其表面粗糙度仅为0.39μm。该复合镀层的硬度较Co-W合金镀层增大约76 HV,表现出良好的耐磨性能和高温抗氧化性能,摩擦系数和氧化增重量仅为0.43和0.74mg/cm^(2)。

CeO_(2)颗粒对7075铝合金微弧氧化膜生长行为及耐磨/耐蚀性能的影响

目的通过CeO_(2)颗粒复合,进一步改善铝合金微弧氧化膜的耐磨和耐蚀性能。方法在硅酸盐-磷酸盐电解液体系中加入CeO_(2)颗粒,利用微弧氧化技术在7075-T6铝合金表面制备CeO_(2)颗粒复合氧化膜;从氧化电压、放电行为及膜层厚度的变化规律探讨CeO_(2)颗粒含量对微弧氧化膜生长过程的影响;通过扫描电子显微镜、动电位极化曲线、球-盘磨损试验等研究电解液中CeO_(2)颗粒浓度对微弧氧化膜微观结构、耐磨性能和耐蚀性能的影响。结果通过CeO_(2)颗粒的复合,改变了铝合金微弧氧化成膜过程的能耗分布,加速了微弧氧化膜的放电击穿。CeO_(2)颗粒复合会使膜层的生长速率有所下降,但氧化膜的致密性、均匀性及膜基的结合强度得到明显改善。CeO_(2)颗粒主要以熔融和嵌合等方式存在于氧化膜中。相较于普通微弧氧化膜,复合膜的摩擦因数普遍降低了约0.2,比磨损率也更低,耐磨性更佳。此外,复合膜呈现出更好的耐腐蚀性,其自腐蚀电流密度至少下降了50%,且在模拟海水中浸泡2000 h后腐蚀增重更小、腐蚀更轻微。在电解液中加入10 g/L的CeO_(2)颗粒时,所得复合膜的综合性能较佳。结论CeO_(2)颗粒复合以熔融或嵌合的方式沉积到铝合金微弧氧化膜中,有效减少了膜层的微孔等缺陷,提高了膜层的致密性和硬度,改善了膜层的耐蚀性和耐磨性。

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。

纳米CeO_(2)掺杂的YBCO超导块材的制备及其性能

本文采用两种熔渗生长工艺(011-IG和211-IG)制备纳米CeO_(2)掺杂的Y-Ba-Cu-O(YBCO)超导块材,同时使用一种坑式籽晶模式来阻止薄膜籽晶在热处理过程中的移动,随后对样品的生长形貌、微观结构和超导性能进行研究.结果表明,在低掺杂量(质量分数为1%)下,YBCO晶体的正常生长不会受到影响,用两种工艺均能成功制备生长完全的单畴YBCO超导块材,且籽晶的位置没有发生任何移动,证明了新籽晶模式的有效性.扫描电子显微镜结果表明,纳米CeO_(2)掺杂可以有效细化超导块材内Y_(2)BaCuO_(5)(Y-211)微米级粒子的尺寸,且该方法对两种工艺均有效.低温磁性测试结果表明,011-IG法制备的纳米CeO_(2)掺杂的样品在低外场下呈现出比未掺杂样品明显优越的J_(c)性能,说明细化的Y-211粒子可以有效地提高δl型钉扎.此外,相比211-IG法制备的样品,011-IG法制备的样品在磁悬浮力、微观形貌和J_(c)性能等方面表现更优越,因此011-IG法是一种更有潜力的制备工艺.本文结果对进一步提高YBCO超导块材的性能和优化制备工艺有重要意义.

静电纺丝法制备CeO_(2)/CuCrO_(2)纳米线及其微结构与光学特性分析

本文采用静电纺丝法制备了CeO_(2)/CuCrO_(2)纳米线,采用XRD、SEM、TEM、EDS及UV-Vis等手段分析了其微结构与光学特性。微结构分析表明,所有样品中都只有CeO_(2)与CuCrO_(2)两种目标相,材料表面呈纤维状结构,直径为70~90 nm,纤维表面的晶粒尺寸皆控制在24nm以内,表明采用静电纺丝法能够成功制备出具有小晶粒的CeO_(2)/CuCrO_(2)纳米线。光学特性分析表明,在可见光范围内样品的吸收度随着CeO_(2)/CuCrO_(2)摩尔比的减小而逐渐变大,即CuCrO_(2)占比越多的纳米线其光学吸收性越好,光学能隙约在2.95~2.98eV之间。

Modification of Nano-α-Al2O3 and Its Influence on the Surface Properties of Waterborne Polyurethane Resin Composite Passivation Films

Silane coupling agent KH560 was used to modify the surface of nano-α-Al2O3 in ethanol-aqueous solution with different proportions. The particle size of nano-α-Al2O3 was determined by nano-particle size analyzer, and the effects of nano-α-Al2O3 content, ethanol-aqueous solution ratio and KH560 dosage on the dispersion and particle size of nano-α-Al2O3 were investigated. The material structure before and after modification was determined by Fourier transform infrared spectroscopy (FTIR). Aqueous polyurethane resin and inorganic components are combined with modified nano-α-Al2O3 dispersion to form chromium-free passivation solution. The solution is coated on the galvanized sheet, the adhesion and surface hardness are tested, the bonding strength of the coating and the surface hardness of the substrate are discussed. The corrosion resistance and surface morphology of the matrix were investigated by electrochemical test, neutral salt spray test and scanning electron microscope test. The chromium-free passivation film formed after the modification of nano-α-Al2O3 increases the surface hardness of galvanized sheet by about 85%. The corrosion resistance of the film is better than that of a single polyurethane film. The results show that the surface hardness and corrosion resistance of polyurethane resin composite passivation film are significantly improved by the introduction of nano-α-Al2O3.

掺入纳米CeO_(2)颗粒对Ti6Al4V的微弧氧化涂层性能的影响

采用脉冲电源在磷酸盐和硅酸盐等复合电解液下对Ti6Al4V钛合金进行表面陶瓷化处理,并研究在电解液中掺杂不同质量浓度CeO_(2)颗粒制备出的陶瓷涂层性能的变化,确定最佳掺杂浓度。应用XRD、SEM和EDS等手段表征了MAO涂层的物相组成、表面形貌和元素组成,并对比分析了CeO_(2)颗粒掺杂前后的厚度变化和电化学腐蚀行为。制备出的MAO陶瓷涂层具有复杂的多相复合结构,主要以金红石TiO_(2)和锐钛矿TiO_(2)为主,含有部分Al_(2)TiO_(5)和SiO_(2)相,另外还含有晶态的Al2O3和少量非晶态Al2O3;在电参数、反应时间和电解液温度不变的条件下,在电解液中掺杂CeO_(2)能轻微提高MAO涂层的厚度,并改变各相之间的转化率,提高氧化膜的耐蚀性。随着掺杂质量浓度的提高,膜层的光滑度先提高后降低,膜厚逐渐增加,耐蚀性先提高后降低;掺杂质量浓度为1.00 g·L^(-1)时平均膜厚达到12.02μm,涂层表面最光滑,涂层的致密性最好,致密层电阻Rb大大提高,此时的腐蚀速率最低为0.79μm·a^(-1),耐蚀性最好。

Preparation, Structures Nano TiO_2 Particles, and the properties of TiH_2 Coated with Nano TiO_2

The surface of Titanium Hydride (TiH 2) is coated by Nano Titanium Dioxide (TiO 2) particles prepared in both of methods of hydrolysis reaction of Ti(OC 4H 9) 4 and base precipitation reaction of Ti(SO 4) 2. TiH 2 coated with nano TiO 2 particles, in which there is an oxidation film on its surface, shown in the experiments, will obviously achieve good effects on releasing hydrogen slowly in high temperature. There are different structures and properties of TiH 2 coated by nano TiO 2 particles prepared in different ways in high temperature, which can influence on releasing hydrogen.

Synthesis,characterization and gas-sensing properties of Pd-doped SnO_2 nano particles

SnO2 nano particles with various Pd-doping concentrations were prepared using a template-free hydrothermal method.The effects of Pd doping on the crystal structure,morphology,microstructure,thermal stability and surface chemistry of these nano particles were characterized by transmission electron microscope,X-ray diffractometer and X-ray photoelectron spectroscope respectively.It was observed that Pd-doping had little effect on the grain sizes of the obtained SnO2 nano particles during the hydrothermal route.During thermal annealing,Pd-doping could restrain the growth of grain sizes below 500℃ while the grain growth was promoted when the temperature increased to above 700℃.XPS results revealed that Pd existed in three chemical states in the as-synthesized sample as Pd^0,Pd^2＋ and Pd^4＋,respectively.Pd^4＋ was the main state which was responsible for improving the gas-sensing property.The optimal Pd-doping concentration for better gas-sensing property and thermal stability was 2.0%-2.5% （mole fraction）.

铜锌合金表面CeO_(2)颗粒掺杂微弧氧化复合膜层的制备及性能分析

目的提高铜锌合金的耐蚀性,对黄铜表面进行颗粒掺杂微弧氧化(MAO),研究纳米颗粒CeO_(2)对复合膜层性能的影响。方法以Na_(2)SiO_(3)·9H_(2)O、NaOH的混合溶液作为电解液,对铜锌合金进行微弧氧化,以膜层厚度和自腐蚀电流密度为评价指标,对氧化时间、正向电压、反向电压、占空比进行正交试验和极差分析,得到最佳微弧氧化电参数。将CeO_(2)添加到混合电解液中,以制备颗粒掺杂微弧氧化复合膜层。通过SEM、EDS、XRD、动电位极化曲线和电化学交流阻抗测试等手段,研究CeO_(2)纳米颗粒对膜层表面、横截面的微观形貌和成分组成及膜层表面的物相结构和耐蚀性能的影响。结果以自腐蚀电流密度为主要评价指标,兼顾膜层厚度,通过正交试验和极差分析,得到了铜锌合金微弧氧化最佳电参数组合,氧化时间为80 min,占空比为20%,正向电压为550 V,反向电压为5 V。未添加CeO_(2)的黄铜试件,微弧氧化膜层表面存在粗糙多孔的结构;掺杂纳米颗粒CeO_(2)后,复合膜层表面变得更为平整,表面粗糙度Ra值从3.883μm降至3.331μm,孔隙率也由颗粒掺杂前的35.11%降至32.98%。随着CeO_(2)颗粒的掺杂,膜层表面的C、O、Si、Ce元素增加,Cu、Zn元素下降,膜层表面的物相主要由CuO、ZnO、CeO_(2)和SiO_(2)组成。纳米颗粒CeO_(2)掺杂前后,膜层均与黄铜基体结合紧密,无明显裂缝。沿着膜层表面向基体方向,Cu和Zn元素含量短暂上升后保持平稳,而O和Si元素含量变化情况为先增加、后减小至消失。颗粒掺杂前,MAO膜层的自腐蚀电流密度J_(corr)为8.095×10^(-4)A/cm^(2),掺杂纳米颗粒CeO_(2)后,J_(corr)为7.402×10^(-5)A/cm^(2)。两者与黄铜基体的J_(corr)(1.236×10^(-2)A/cm^(2))相比,分别下降了2、3个数量级。结论对铜锌合金进行微弧氧化可以在合金表面制得多孔且有良好耐蚀性的陶瓷膜层。纳米颗粒CeO_(2)的掺杂,能够有效改善铜锌合金微弧氧化膜层的多孔结构,降低孔隙率,阻碍外界腐蚀离子的侵入,增强膜层的耐腐蚀性能。

Fe_(3)O_(4)/GO/CeO_(2)复合纳米材料的制备及其对水中亚甲基蓝吸附性能研究

首先通过溶剂热法制备Fe_(3)O_(4)纳米颗粒,再通过离子强度调控法制备磁性氧化石墨烯(Fe_(3)O_(4)/GO),最后用共沉淀法制得Fe_(3)O_(4)/GO/CeO_(2)复合纳米材料,并用扫描电镜(SEM)、能量色散X射线光谱(EDX)、X射线衍射(XRD)等技术对其进行表征。结果表明:Fe_(3)O_(4)纳米颗粒与CeO_(2)纳米颗粒均匀地分散在GO上。研究了Fe_(3)O_(4)/GO/CeO_(2)复合纳米材料对亚甲基蓝染料的吸附性能,并考察了不同因素对吸附性能的影响。由于Fe_(3)O_(4)纳米颗粒有着磁性的性质,易回收分离,具有再生利用性能。吸附实验结果表明:Fe_(3)O_(4)/GO/CeO_(2)复合纳米材料循环5次后对亚甲基蓝的吸附率仍在95%以上。因此,Fe_(3)O_(4)/GO/CeO_(2)复合纳米材料是一种新型优良的吸附剂材料,被应用于模拟染料废水中的亚甲基蓝去除研究。

纳米SiO_(2)表面改性稳定非水相泡沫的实验研究

非水相泡沫在石油开采、功能材料、日用化工等领域有着广泛的应用,非水相泡沫的研究进展影响着相关行业的发展。然而,由于其自身的界面张力和介电常数较低,致使发泡难度较大。为解决非水相体系发泡困难的问题,文章通过制备纳米SiO_(2)颗粒,经TEM,FT-IR及XRD对颗粒进行表征,采用3-缩水甘油氧基丙基三甲氧基硅烷(GPTMS)对纳米SiO_(2)颗粒润湿性进行调控,研究纳米SiO_(2)颗粒对非水相溶剂发泡性能的影响。结果表明:经GPTMS改性后,颗粒的接触角范围扩大至34.7°~116°之间;且能有效降低不同溶剂的表面张力并增加溶剂体系的黏度;当颗粒质量分数为7%,粒径为10 nm时,非水相产生的泡沫体积随纳米SiO_(2)颗粒接触角的增大呈现先增后减的趋势,泡沫稳定性随纳米SiO_(2)颗粒接触角的增大呈现先增强后减弱的趋势。在甲酰胺体系中,当颗粒接触角为92.3°时,泡沫体积最高可达到12 mL,泡沫稳定时长可达63 d;在乙酸苄酯体系中,当颗粒接触角为79.5°时,泡沫体积最高可达到7 mL,泡沫稳定时长可达47 d;在癸烷体系中,当颗粒接触角为60.3°时,泡沫体积最高可达到4 mL,泡沫稳定时长可达8 d。

Effect of CeO_(2)on Activity of Catalysts CuO/ZnO/Al_(2)O_(3)/CeO_(2)for Synthesis of Methanol

The size of the nanoparticles and the number of oxygen vacancies have a significant effect on the catalytic activity of copper-based catalysts used for the synthesis of methanol from syngas.In this study,the authors prepared a series of catalysts CuO/ZnO/Al_(2)O_(3)/CeO_(2)(CZAC)with CuO particles of different sizes and varying number of oxygen vacancies on the surface by changing the added volume of CeO2 by using the co-precipitation method.The properties of the catalysts were characterized and their activity was evaluated by using high-pressure fixed-bed reaction equipment.The results showed that the addition of CeO_(2)to CuO/ZnO/Al_(2)O_(3)not only influenced the size of the CuO particles and metal-metal interactions,but also had an effect on the concentrations of oxygen vacancies and strongly basic sites.The presence of CuO particles of small sizes and a large numbers of oxygen vacancies on the surface of the catalyst were beneficial to its activity for the synthesis of methanol.The catalyst CZAC,when modified by 5%of CeO_(2),recorded CuO particles of the smallest size(8.9 nm),strong intermetallic interactions,and the highest concentrations of oxygen vacancies and strongly basic sites.It also exhibited the highest catalytic activity,with a space-time yield of methanol of 0.315 g/(h·g)that was higher than that of the enterprise RK-5 catalyst[0.215 g/(h·g)].

n-CeO_(2)与CTBN/EP共混增韧改性及其机理研究

采用物理共混的方法制备以端羧基丁腈橡胶(CTBN)和纳米二氧化铈(n-CeO_(2))为增韧剂对环氧树脂(EP)进行增韧的复合材料,利用XRD、FTIR、SEM及万能拉伸试验仪,研究了在15 phrCTBN下不同n-CeO_(2)含量对复合材料力学性能的影响。结果表明,当n-CeO_(2)含量为5 phr时增韧效果最好,n-CeO_(2)-CTBN/EP的拉伸强度达73.2 MPa,弯曲强度达191.4 MPa,冲击强度达31.1 KJ/m^(2),较未添加n-CeO_(2)的CTBN/EP分别提高了16.1%、112%、42.2%。

NaCl对糖-尿素法制备纳米CeO_(2)颗粒的影响

为寻找一种绿色高效的纳米CeO_(2)制备方法,采用葡萄糖-尿素低共熔体系作为溶剂,一步法制备出纳米CeO_(2)并使用NaCl作为阻隔剂提高其分散性。采用X射线衍射、扫描电子显微镜、透射电镜等表征手段对材料进行表征测试。结果表明:所制备的纳米CeO_(2)均为球形,粒径分布2~9 nm。随着NaCl添加量的增加,CeO_(2)的粒径、分散性及比表面积均呈现先增加后减少的趋势,当硝酸铈与NaCl的质量比为1∶3时,CeO_(2)-5粒径最小为2.51 nm,比表面积最大为75 m^(2)/g,分散程度最好。因此,合适的NaCl添加量有利于分散的纳米CeO_(2)形成。

Factors Affecting the Reductive Properties of the Core-Shell SiO2-Coated Iron Nanoparticles

In this study, novel core-shell SiO2-coated iron nanoparticles (SiO2-nZVI) were synthesized using a one-step Stoeber method. The Malachite green degradation abilities of the nanoparticles were investigated. The effects of ethanol/distilled water volume ratio, presence and absence of PEG, tetraethyl orthosilicate (TEOS) dosage, and hydrolysis time used in the nanoparticles preparation process were investigated. The results indicated that the SiO2-coated iron nanoparticles had the highest reduction activity when the particles synthesized with ethanol/H2O ratio of 2:1, PEG of 0.15 ml, TEOS of 0.5 ml and the reaction time was 4 h. The SiO2-nZVI nanoparticles were characterized using Transmission Electron Microscopy (TEM), Energy Dispersive Spectrometry (EDS) and powder X-Ray Diffraction (XRD). The results showed that the average particles diameter of the SiO2-nZVI was 20 - 30 nm. The thickness of the outside SiO2 film is consistent and approximately 10 nm. The results indicated that the nanoparticles coated completely with a transparent SiO2-film. Such nanoparticles could have wide applications in dye decolorization.

CuO纳米颗粒修饰的TiO_(2)纳米管的制备及其性能研究

本研究采用水热法制备了CuO纳米颗粒修饰的TiO_(2)纳米管,采用XRD、ICP-MS、SEM、TEM及UV-Vis等手段,分析了TiO_(2)纳米管的基本物理特性,并将其应用于水解制氢反应中。基本物性分析表明,Cu掺杂对TiO_(2)的晶体结构没有明显的影响,CuO纳米颗粒可成功负载于TiO_(2)纳米管表面,其中Cu掺杂量为3wt%的样品,其结晶性最佳,且表面分布的CuO颗粒数量最为适当。在TiO_(2)纳米管表面负载适量的CuO颗粒,可将其吸收波段从紫外光区红移至可见光区,有效提升其光学活性。水解制氢的实验结果表明,经CuO颗粒修饰后,TiO_(2)纳米管的光催化性能得到大幅提升,其中Cu掺杂量为3wt%时,纳米管的H_(2)产率最高,可达47082μmol·g^(-1);Cu掺杂过量时,会因遮蔽效应而降低纳米管的光催化性能,但H_(2)的产率仍可提升约10倍。

Effectiveness of Bark Extracts and CeO2 Nano Particles as Coating Additives for the Protection of Heat-Treated Jack Pine

High temperature heat-treatment of wood, which is value-added green product, is one of the altematives to chemical treatment. It has better dimensional stability, thermal insulating properties and biological resistance compared to kiln dried wood. It also has dark brown color which is very important for decorative purposes. Unfortunately, this color changes during weathering. Developing a transparent and non-toxic coating for the protection of heat-treated wood against discoloration without changing its natural appearance is the main objective of this study. For this purpose, waterborne acrylic polyurethane base was chosen because of its durability against weathering and non-toxic nature. Natural antioxidants which are extracted from barks and CeO2 nano particles （alone or together with lignin stabilizer） were used as additives to develop different coatings. The protective characteristics of these coatings were compared with highly pigmented and toxic industrial coating under accelerated weathering conditions. The results showed that acrylic polyurethane coatings protected wood better compared to commercially available coating tested in this study. The chemical modifications during accelerated weathering of coated and heat-treated wood surfaces were monitored by X-ray photoelectron spectroscopy analysis. The morphological changes took place during weathering were studied by fluorescence microscope analysis.

硅烷/纳米CeO_(2)·ZrO_(2)复合膜层的制备及其性能研究

针对低温多效海水淡化过程中金属换热管路的腐蚀问题,采用硅烷(APS)、纳米氧化锆(ZrO_(2))及纳米氧化铈(CeO_(2))在铝合金表面制备硅烷/纳米ZrO_(2)·CeO_(2)复合膜层,研究其抑制金属腐蚀的效果。结果表明,当纳米ZrO_(2)、纳米CeO_(2)添加浓度为50 mg/L时,复合膜层的综合性能较好;通过动电位极化法和电化学阻抗法探究了复合膜层在不同温度下的耐蚀性能,结果表明硅烷/纳米ZrO_(2)·CeO_(2)复合膜层的防护效果较单一硅烷膜层有明显提升。随着溶液温度的升高,硅烷/纳米ZrO_(2)·CeO_(2)复合膜层的耐蚀性能降低较少,纳米ZrO_(2)、纳米CeO_(2)的协同作用使得硅烷膜更能适应高温高盐环境。

KIT‑6负载CeO_(2)催化CO_(2)和甲醇合成碳酸二甲酯

采用不同老化温度(80、100、120和150℃)合成了一系列KIT‑6载体,并通过浸渍法制备了相应的CeO_(2)/KIT‑6催化剂。结合X射线衍射、N2物理吸附、NH_(3)程序升温脱附、CO_(2)程序升温脱附、透射电子显微镜、傅里叶变换红外光谱和X射线光电子能谱等表征结果,详细考察了老化温度对KIT‑6结构以及CeO_(2)/KIT‑6催化剂直接催化CO_(2)和甲醇合成碳酸二甲酯(DMC)反应活性的影响。结果表明,不同老化温度下制备的KIT‑6均保持其独特的三维孔道结构。随着老化温度升高,KIT‑6比表面积先增大后减小,当老化温度为100℃时,KIT‑6比表面积达到最大(683 m^(2)·g^(-1))。KIT‑6较高的比表面积有利于提高CeO_(2)分散度,进而提高暴露的活性位点数量,催化活性随催化剂表面中等碱/酸性吸附位数量和Ce3+含量的增加而逐渐提高。其中,CeO_(2)/100‑KIT‑6催化剂中CeO_(2)颗粒尺寸最小(5.9 nm),暴露的活性位数量最高,催化活性最佳。随后,考察了反应温度和压力对CeO_(2)/100‑KIT‑6催化活性的影响。随着反应温度提高,催化活性先升高后降低,当反应温度为140℃时,催化活性最高;且催化活性随反应压力的提高而逐渐增加。在反应温度为140℃、压力为6.8 MPa条件下,催化剂经6次循环后,DMC收率由15 mmol·gCeO_(2)^(-1)逐渐降低至2.8 mmol·gCeO_(2)^(-1),原因归结为反应过程中CeO_(2)纳米颗粒发生团聚,使暴露出的活性位数量减少。