氢键诱导的聚吡咯/苯磺酸功能化多壁碳纳米管的制备及其电化学行为

采用原位芳基重氮化反应对碳纳米管进行苯磺酸功能化, 进而制备了聚吡咯/苯磺酸化碳纳米管复合材料(PPy/f-MWCNTs), 通过透射电镜(TEM)及扫描电镜(SEM)测试发现, 氢键诱导使聚吡咯成功地包覆在碳纳米管表面. 循环伏安和恒流充放电测试结果表明, 复合材料具有良好的电化学电容性能, 当聚吡咯与苯磺酸化碳纳米管质量比为1:1时, 复合材料在1.0 A·g-1的电流密度下的比容量达266 F·g-1, 而且聚吡咯利用率比未功能化聚吡咯/碳纳米管(PPy/p-MWCNTs)和纯聚吡咯(PPy)提高了1倍以上.     

咪唑基介孔有机硅材料固载磷钼酸催化剂的制备及烯烃环氧化性能

以含有咪唑阳离子的周期性介孔有机硅（PMO-ILs）材料为载体,制备了一类固载化磷钼酸（PMA）多相催化材料（PMA@PMO-ILs）,并采用N₂吸附-脱附实验、X射线衍射、原子吸收光谱、差热-热重分析、红外光谱、紫外光谱及固体核磁共振技术研究了材料的结构及物理化学性质. 结果表明,磷钼酸通过静电相互作用被成功固载到PMO-ILs载体表面和孔道中,且在制备过程中磷钼酸及载体基本结构均未发生变化. 反应结果表明,PMA@PMO-ILs材料在以叔丁基过氧化氢为氧化剂的环辛烯环氧化反应中表现出一定的催化活性和很高的选择性. 中断实验结果表明,催化剂的主要活性中心在反应过程中未发生明显流失,且催化剂经多次循环使用后活性及选择性基本保持不变. PMO-ILs中大量的咪唑阳离子能有效稳定磷钼酸阴离子,使该催化材料表现出良好的稳定性.     

毛细管电泳-多壁碳纳米管/聚吡咯/磷钼酸修饰电极电化学检测饮用水中的溴酸根

用电化学聚合法制备多壁碳纳米管/聚吡咯/磷钼酸修饰电极,利用循环伏安法研究溴酸根在此修饰电极上的电化学行为.考察了实验参数对分离检测体系的影响,并在优化条件下,采用毛细管电泳-安培检测法对溴酸根进行检测.结果表明:溴酸根离子在1.0×10-6～5.0×10-3 mol/L范围内和峰面积呈良好的线性关系,检出限(S/N=...     

Dawson型钒代磷钼酸在酮/醇缩合中的催化性能

合成了Dawson型磷钼酸和钒取代磷钼酸, 用UV-Vis、 IR和XRD表征了结构, 用pH计考察了在不同介质中的酸性. 以苯乙酮和醇的缩合反应作为探针反应, 考察了磷钼酸中钒含量、磷钼酸用量及醇用量等因素对磷钼酸催化性能的影响. 结果表明, 钒取代钼后使Dawson型磷钼酸在有机介质中的酸性减弱. 当H_6P_2Mo_(18)O_(62)∶苯乙酮∶乙二醇的物质的量比为6∶1000∶2000, 回流反应6 h时, 缩酮收率为89.2 %. 在合成缩酮的反应中, 磷钼酸的"假液相"性使其催化活性明显增强, 但随着钒取代数增加, 钒取代磷钼酸的催化性能减弱;醇分子的空间位阻增大, 磷钼酸的催化活性也降低.     

四羰基钴/咪唑离子液体在羰基化合成丙二酸二甲酯反应中的催化性能

采用原位法合成了不同类型的四羰基钴/咪唑离子液体催化剂,并考察了其在氯乙酸甲酯羰基化反应中的催化性能.研究了咪唑环上不同支链对催化活性的影响.结果表明,1-丁基-3-甲基咪唑羰基钴离子液体[Bmim][Co(CO)4]不仅催化活性高,选择性好,而且对空气和水有较好的稳定性能.在pCO=2.0 MPa,85℃,反应3 h的条件下,[Bmim][Co(CO)4]催化剂循环使用4次,氯乙酸甲酯的平均转化率为94.3%,丙二酸二甲酯的平均选择性和平均产率分别为98.5%和92.9%.与传统的Na[Co(CO)4]催化剂相比,[Bmim][Co(CO)4]催化剂在保证高活性的条件下可以实现羰基钴催化剂的直接循环使用.     

溶剂热法制备磷掺杂碳纳米管作为氧气还原和氧气析出反应双功能电催化剂的研究

对氧气还原(ORR)和氧气析出(OER)反应都具有催化活性的双功能催化剂在金属-空气电池中起着关键作用.本文通过溶剂热反应,一步原位合成了磷掺杂碳纳米管(P-CNT).旋转环盘电极测试表明磷掺杂能够明显提高碳纳米管的催化活性,P-CNT在碱性电解质中对ORR和OER都具有优异的催化活性.P-CNT对ORR的催化还原为近4电子反应,可与商业催化剂Pt/C(20 wt%)相比;而其对OER的催化活性则高于Pt/C(20 wt%).此外,P-CNT的长期稳定性优于Pt/C(20 wt%).P-CNT对ORR和OER的高催化活性和稳定性主要归因于磷对碳的掺杂以及磷与碳间强的化学键合.     

可回收(S)-脯氨醇衍生物在催化查尔酮类化合物不对称环氧化反应中的催化性能研究

将以L-脯氨酸为原料合成的光学活性脯氨醇衍生物((S)-2-吡咯烷基-α,α-二(α-萘基)甲醇1),作为有机小分子催化剂,在催化8种α,β-不饱和酮的不对称环氧化反应中表现出较好的立体选择性(58.0~84.6?)和催化活性(58.0~89.7%).反应结束后,通过简单的酸碱调整,可使催化剂回收和重复使用.循环使用5次,催化剂的回收率均在93~97%之间,催化剂的催化活性和立体选择性无明显改变.     

磷钨杂多酸盐／SiO2可逆负载催化剂催化氯丙烯环氧化制环氧氯丙烷

通过原位负载法合成了一种新的具有可逆负载特性的磷钨杂多酸盐/SiO2催化剂,并应用于氯丙烯环氧化反应.在反应温度65℃的条件下,系统研究了原位负载过程中反应时间、调节剂Na2HPO4用量、烯烃/H2O2摩尔比和硅烷化硅胶粒度大小等因素对环氧化反应的影响,并考察了催化剂的循环使用效果.实验结果表明,在适宜的反应条件下,初始反应环氧氯丙烷的产率达86·5%,催化剂循环使用3次,催化活性基本保持不变.     

功能化含磷钼酸介孔硅材料的制备及其在深度氧化脱硫中的应用

随着全球工业的快速发展,化石燃料的消耗量日益增加,从而导致有毒污染物的排放量随之增加.燃料油中的含硫化合物燃烧后会形成SOx.SOx排放到大气中会形成酸雨污染环境.因此,超清洁燃料的生产迫在眉睫.目前主要的脱硫工艺为加氢脱硫(HDS).HDS能够有效脱除燃油中的硫醚、硫醇和二硫化物等含硫化物,但对于芳香族硫化物及其衍生物(如苯并噻吩、二苯并噻吩和4,6-二甲基二苯并噻吩等)的脱除效果较差,而且HDS需要在高温、高压且有合适催化剂存在的条件下进行反应.因此,开发操作简单、反应条件温和、能够高效脱除芳香族硫化物及其衍生物的脱硫工艺已成为目前研究的热点.催化氧化脱硫(CODS)能够在温和条件下高选择性脱除芳香族硫化物及其衍生物,作为HDS的有效补充,在深度脱硫领域的应用得到了广泛认可.目前适用于CODS的催化剂有分子筛、甲酸、过氧化物酶、氧化钼和杂多酸等.其中,含钼(VI)催化剂在CODS中表现出良好的性能,得到了广泛的研究和应用.在CODS中,催化剂载体同样起着重要作用.从实际应用角度出发,无定形二氧化硅在制备过程及经济性方面存在着不可替代的优势.到目前为止,无定形SiO2负载磷钼酸(HPMo)作为CODS催化剂的研究鲜有报道.本课题组以聚乙烯吡咯烷酮(PVP)为介孔模板剂,以正硅酸四乙酯(TEOS)为硅源,通过沉淀法直接合成了功能化含HPMo介孔复合材料HPMo-SiO2.采用XRD,FT-IR,31P-NMR和XPS等测试手段对所制备的材料进行了表征.结果表明,作为催化活性位点的钼以磷钼酸的形式存在,磷钼酸的Keggen结构在负载过程中没有遭到破坏,并且活性磷钼酸能够均匀分散在二氧化硅载体上.HPMo-SiO2的比表面积为365.0 m2/g,总孔容为1.237 cm3/g,平均孔径为12.91 nm.本文系统研究了模型油脱硫反应条件、催化剂循环使用次数及催化反应动力学.结果表明,HPMo-SiO2具有高效的脱硫活性,在反应温度为55oC,催化剂与模型油质量比为0.7%,反应时间为10 min的条件下,二苯并噻吩(DBT)脱除率可达100%;在反应温度为60oC,催化剂与模型油质量比为1.0%,反应时间为30 min的条件下,苯并噻吩(BT)脱除率可达100%.同等反应条件下,DBT的反应活性大于BT.DBT及BT的氧化脱除反应均符合表观一级动力学模型,且DBT脱除反应的表观活化能小于BT脱除反应.所制备的催化剂经过10次循环使用,DBT脱除率仍可以达到95.2%(BT为95.7%),说明所制备的HPMo-SiO2催化剂具有高活性和强稳定性.通过气质联用及微库仑仪对反应产物进行了分析,结果表明,BT和DBT的氧化产物分别为苯并噻吩砜(BTO2)和二苯并噻吩砜(DBTO2),且氧化产物全部被催化剂吸附,油品中没有含硫化合物的存在,因此不需要后续的氧化产物分离操作,提高了整个脱硫工艺的经济性,并且有效减少了分离操作带来的油品损失.     

咪唑四氟硼酸盐离子液体中磷钼酸掺杂聚吡咯薄膜修饰电极的制备及其电催化活性

以1-丁基-3-甲基咪唑四氟硼酸盐(BMIMBF4)离子液体作为介质,利用电化学方法在铂电极表面制备了磷钼酸掺杂聚吡咯薄膜;采用扫描电子显微镜观察了所制备的薄膜的形貌,利用热重分析评价了其热稳定性,利用循环伏安法测定了其电化学活性和对甲醇的电催化氧化活性.结果表明,与传统的硫酸溶液相比,以BMI-MBF4离子液体作为反应介质制备的修饰电极的表面形貌更均匀,电化学活性和对甲醇的电催化氧化活性更强.     

液相还原Ru/CNTs催化氨分解性能研究

近年来各国对环境保护日益关注,为了减少甚至消除汽车、小型发电站等带来的污染,供给质子膜燃料电池(PEMFC)的现场制氢技术的研究受到关注.     

Remarkable binuclear Schiff-based complex catalyze the epoxidation of alkenes: effects of substituent group

A series of dimolybdenum metal catalysts with different ligand have been successfully synthesized and used to catalyze the epoxidation of alkenes to generate epoxides by using tert-butyl-hydroperoxide (TBHP) as oxidant. The reaction condition was optimized by the adjustment of some key parameters, such as, temperature, to target high catalytic performance. The oxidation of cyclooctene gave 95.00% conversion and almost 100.00% selectivity. Kinetic study of the oxidation of cyclooctene under different temperature was taken out, indicating the reaction have good catalytic performance. Furthermore, it is calculated from the Arrhenius equation that different functional groups affect the activation energy of the reaction. The electron donor group substituent on the liagnd increases the catalytic activity by reducing the activation energy, and vice versa. Finally, a possible catalytic mechanism has been proposed by measuring the electronic absorption spectrum of the reaction.     

硅胶负载H6PMo9V3O40催化合成5-硝基水杨醛

采用硅胶负载Keggin型H6PMo9V3O40催化水杨醛与硝酸反应合成5-硝基水杨醛,考察了催化剂负载量、反应时间、反应温度、催化剂用量、硝酸用量和溶剂对反应的影响及催化剂的重复使用性能。实验结果表明,m(水杨醛)∶m(质量分数65%硝酸)∶m(负载量20%H6PMo9V3O40/SiO2)=2.44∶3.00∶3.00,用石油醚作为溶剂,45℃反应2.5 h,水杨醛的转化率为98%,5-硝基水杨醛的选择性为96.8%。催化剂回收容易,重复使用5次后,活性基本不变。     

席夫碱Mo(VI)功能化介孔SiO2的制备及其催化烯烃环氧化研究

采用共缩聚法制备有机-无机杂化材料,以介孔SiO_2材料为载体,分别嫁接席夫碱配体和配位乙酰丙酮钼,得到Mo(VI)席夫碱修饰的介孔SiO_2(Mo-SB-Cl-SiO_2-0.5-1).所制备的材料采用XRD,SEM,N2吸附-脱附和TEM技术对其结构进行了表征.考察了Mo-SB-Cl-SiO_2-0.5-1催化液相烯烃环氧化性能,结果表明:Mo-SB-Cl-SiO_2-0.5-1催化剂对烯烃环氧化具有高的转化率和优良的催化活性.与后嫁接法制备的催化剂相比,Mo-SB-Cl-SiO_2-0.5-1催化剂催化活性得到明显提高,催化环己烯环氧化的转化率和选择性分别为85%和99%.在不同烯烃的研究中,环辛烯具有最高的转化率和选择性,分别为87%和99%.催化剂重复使用4次后,环己烯的转化率没有明显下降,选择性仍然高达98%,表明Mo-SB-Cl-SiO_2-0.5-1具有较好的催化稳定性.     

Conversion of CuO Nanoplates into Porous Hybrid Cu2O/Polypyrrole Nanoflakes through a Pyrrole‐Induced Reductive Transformation Reaction

Porous hybrid Cu₂O/polypyrrole nanoflakes have been synthesized from solid CuO nanoplate templates through the pyrrole‐induced reductive transformation reaction at elevated temperature. The conversion mechanism involves the reductive transformation of CuO to Cu₂O and the in situ oxidative polymerization of pyrrole to polypyrrole. In addition, the morphology of the as‐converted nanohybrids depends on the shape of the CuO precursors. The strategy enables us to transform single‐crystalline CuO nanosheets into hollow hybrid Cu₂O/polypyrrole nanoframes. The ability to transform CuO and an organic monomer into porous hybrid materials of conducting polymer and Cu₂O with macrosized morphological retention opens up interesting possibilities to create novel nanostructures. Electrochemical examinations show that these porous hybrid Cu₂O/polypyrrole nanostructures exhibit efficient catalytic activity towards oxygen reduction reaction (ORR), excellent methanol tolerance ability, and catalytic stability in alkaline solution, thus making them promising nonprecious‐metal‐based catalysts for ORR in alkaline fuel cells and metal–air batteries.     

Effective oxidation of 1,2-cyclooctene by oxo-vanadium(IV) tetradentate Schiff base complexes under 1 atmosphere of molecular oxygen

Development of methods for the understanding of chemical reactivity of high-valent metal-oxo species with respect to organic substrates is important. Here we report a high yield, high TON conversion of cyclooctene using VO (Schiff base) complexes (Figure 1) as catalyst and O₂ as oxidant in MeCN under mild conditions. The results show that catalytic activity increases with a decrease in the number of electron-donating groups. At higher concentration of catalyst and shorter reaction time, a low yield but high selectivity of epoxide was observed.     

Excellent alkene epoxidation catalytic activity of macrocyclic‐based complex of dioxo‐Mo(VI) on supermagnetic separable nanocatalyst

A phenoxybutane‐based Schiff base complex of cis‐dioxo‐Mo(VI) was supported on paramagnetic nanoparticles and characterized using powder X‐ray diffraction, infrared, diffuse reflectance and atomic absorption spectroscopies, scanning and transmission electron microscopies and vibrating sample magnetometry. The separable nanocatalyst was tested for the selective epoxidation of cyclohexene, cyclooctene, styrene, indene, α‐pinene, 1‐octene, 1‐heptene, 1‐dodecene and trans‐stilbene using tert‐butyl hydroperoxide (80% in di‐tert‐butyl peroxide–water, 3:2) as oxidant in chloroform. The catalyst was efficient for oxidation of cyclooctene with 100% selectivity for epoxidation with 98% conversion in 10 min. We were able to separate magnetically the nanocatalyst using an external magnetic field and used the catalyst at least six successive times without significant decrease in conversion. The turnover frequency of the catalyst was remarkable (2556 h^?1 for cyclooctene). The proposed nanomagnetic catalyst has advantages in terms of catalytic activity, selectivity, catalytic reaction time and reusability by easy separation.     

The nickel-substituted quasi-Wells-Dawson-type polyfluoroxometalate,

A series of transition metal substituted polyfluorooxometalates (PFOM) [M(L)H2F6NaW17)55]q-, M= Zn2+ , Co2+, Mn2+, Fc2+, Ru2+, Ni2+ and V5+ and L=H2O, O2-, of quasi-Wells-Dawson structure, was synthesized. In the series prepared, only the nickel-substituted polyfluorooxometalate was capable of catalytic activation of hydrogen peroxide in biphasic reaction media, the reaction leading mainly to the selective epoxidation of alkenes and alkenols. The manganese-, cobalt-, ruthenium-, iron-, vanadium-, and zinc-substituted polyfluorooxometalates were catalytically inactive, although, except for the zinc polyfluorooxometalate, very significant catalase activity was observed. Oxidation of thianthrene showed that sulfoxides were oxidized more easily than sulfides. Kinetic profiles of cyclooctene epoxidation showed that the reaction was zero order in both cyclooctene and hydrogen peroxide. Hydrogen peroxide was consumed at a rate 40% higher than the rate of epoxidation of cyclooctene. The reaction appears to proceed through an intermediate peroxo/hydroperoxo species that was observed in the IR spectrum. Atomic absorption, IR and 19F NMR spectroscopy indicated that the [Ni(H2O)H2F6NaW17O55]9- compound was stable under reaction conditions.     

介孔Cs3PMo12O40的制备、表征及其醛糖差向异构化反应的催化性能

以磷钼酸和氯化铯为原料、三嵌段共聚物F127为模板剂制备Keggin型介孔Cs₃PMo₁₂O₄₀(简称m?Cs₃PMo),通过X射线粉末衍射(XRD)、FT?IR、场发射扫描电子显微镜(FESEM)、透射电子显微镜(TEM)、N₂吸附-脱附测试和小角X射线散射(SAXS)对催化剂的组成、结构、形貌进行了表征。结果表明,m?Cs₃PMo属于立方相晶系,具有2.5和6.0 nm的蠕虫状介孔。以m?Cs₃PMo为催化剂考察其水相中D?葡萄糖、D?木糖和L?阿拉伯糖差向异构化反应的催化性能,并研究了反应温度、时间和催化剂用量对D?葡萄糖差向异构化反应的影响以及催化剂的循环使用性能,在循环使用过程中m?Cs₃PMo表现出良好的稳定性。     

Oxidative coupling of benzenes with alpha,beta-unsaturated aldehydes by the Pd(OAc)2/molybdovanadophosphoric acid/O2 system

[reaction: see text] The oxidative coupling reaction of benzene with an alpha,beta-unsaturated aldehyde was examined by the combined catalytic system of Pd(OAc)2 with molybdovanadophosphoric acid (HPMoV) under atmospheric dioxygen. Thus, the reaction of benzene with acrolein under dioxygen (1 atm) by the use of catalytic amounts of Pd(OAc)2 and H4PMo11VO40 x 26H2O in the presence of dibenzoylmethane as a ligand in propionic acid at 90 degrees C for 1.5 h afforded cinnamaldehyde in 59% yield and beta-phenylcinnamaldehyde in 5% yield. This catalytic system was extended to the direct oxidative coupling through the C-H bond activation of various arenes with acrolein and methacrolein.