Ru-[bmim]BF4 的制备及催化苯选择加氢反应性能

以离子液体1-丁基-3-甲基咪唑四氟硼酸盐([bmim]BF4)-水混合溶剂为介质,采用化学还原法制备了Ru-[bmim]BF4催化剂,并利用紫外-可见光谱、红外光谱、透射电镜、X射线衍射和X射线光电子能谱对催化剂进行了表征.结果表明,Ru在[bmim]BF4中分散较好,粒径~2nm,且离子液体中咪唑阳离子与部分Ru形成了金属卡宾配合物.利用苯选择加氢反应对该催化剂性能进行了评价,发现Ru-卡宾配合物存在时,催化剂活性较低,但环己烯选择性较高.在本文反应条件下,苯转化率为12.2%,环己烯选择性为40.5%.重复使用该催化剂时,由于Ru-卡宾配合物在反应中转变为Ru0,其催化活性增加,但环己烯选择性下降.继续多次使用该催化剂,其性能基本保持稳定.     

功能化离子液体中Ag纳米微粒的制备及摩擦学性能研究

合成了1-甲基-3-羟乙基咪唑四氟硼酸盐离子液体([C₂OHmim]BF₄)，用红外光谱表征了其结构。以所合成的离子液体作为还原剂、稳定剂与反应介质制备了Ag纳米微粒，用XRD和TEM对微粒的结构和形貌进行了表征。在四球摩擦磨损实验机上研究了[C₂OHmim]BF₄离子液体及掺入Ag纳米微粒后的离子液体的摩擦学性能。掺入银纳米微粒后，离子液体在高载荷下的润滑性有了大幅的改善。用SEM和XPS分别对磨痕表面的形貌和元素组成、化学状态进行了分析，结果表明：在低、高载荷分别起润滑作用的是有机膜和金属-有机复合膜。     

酸性离子液体中铂纳米粒子的制备、表征及应用

基于功能化离子液体的特性,开发出不使用聚合物保护剂制备铂纳米粒子并同时获得具有金属和酸活性中心双功能催化剂的新方法。首先,设计并合成出了一种新型季铵型质子(Br?nsted)酸性离子液体(N, N, N-三甲基-N-磺丁基硫酸氢铵([HSO₃-b-N(CH₃)₃]HSO₄)),然后,利用化学还原方法在该离子液体中制备了金属铂纳米粒子,并采用紫外光谱、傅立叶红外光谱、X-光电子能谱、透射电子显微镜和X射线衍射等方法对所制备的金属铂纳米粒子进行了结构表征。结果表明,所制备的铂纳米粒子具有面心立方结构,离子液体作为修饰剂修饰在铂纳米粒子的表面,有效地阻止了铂纳米粒子的团聚;将该含有铂纳米粒子的酸性离子液体作为双功能催化剂,直接用于硝基苯加氢合成对氨基苯酚反应,发现其具有良好的催化性能,在85 ℃、4 h、0.4 MPa条件下,硝基苯转化率为98.6%,对氨基苯酚收率为75.8%,回收的酸性离子液体纳米铂双功能催化体系中铂纳米粒子依然具有很好的分散性和稳定性。     

ZnSO4和La2O3作共修饰剂单金属Ru催化剂上苯选择加氢制环己烯

用沉淀法制备了单金属纳米Ru（0）催化剂,考察了ZnSO₄和La₂O₃作共修饰剂对该催化剂催化苯选择加氢制环己烯性能的影响,并用X射线衍射（XRD）、X射线荧光（XRF）光谱、X射线光电子能谱（XPS）、俄歇电子能谱（AES）、透射电镜（TEM）和N₂物理吸附等手段对加氢前后催化剂进行了表征. 结果表明,在ZnSO₄存在下,随着添加碱性La₂O₃量的增加,ZnSO₄水解生成的（Zn（OH）₂）₃（ZnSO₄）（H₂O）_x（x=1,3）盐量增加,催化剂活性单调降低,环己烯选择性单调升高. 当La₂O₃/Ru 物质的量比为0.075 时,Ru催化剂上苯转化率为77.6%,环己烯选择性和收率分别为75.2%和58.4%. 且该催化体系具有良好的重复使用性能. 传质计算结果表明,苯、环己烯和氢气的液-固扩散限制和孔内扩散限制都可忽略. 因此,高环己烯选择性和收率的获得不能简单归结为物理效应,而与催化剂的结构和催化体系密切相关. 根据实验结果,我们推测在化学吸附有（Zn（OH）₂）₃（ZnSO₄）（H₂O）_x（x=1,3）盐的Ru（0）催化剂有两种活化苯的活性位：Ru⁰和Zn²⁺. 因为Zn²⁺将部分电子转移给了Ru,Zn²⁺活化苯的能力比Ru⁰弱. 同时由于Ru和Zn²⁺的原子半径接近,Zn²⁺可以覆盖一部分Ru⁰活性位,导致解离H₂的Ru⁰活性位减少. 这导致了Zn²⁺上活化的苯只能加氢生成环己烯和Ru（0）催化剂活性的降低. 本文利用双活性位模型来解释Ru基催化剂上的苯加氢反应,并用Hückel分子轨道理论说明了该模型的合理性.     

纳米Ru-Mn/ZrO2催化剂上苯选择加氢制环己烯

采用共沉淀法制备了一系列不同Mn含量的纳米Ru-Mn催化剂,考察了纳米ZrO₂作分散剂时它们催化苯选择加氢制环己烯的反应性能,并采用X射线衍射、透射电镜、N₂物理吸附、X射线荧光、原子吸收光谱和俄歇电子能谱等手段对催化剂进行了表征.结果表明,Ru-Mn催化剂上Mn以Mn₃O₄存在于Ru的表面上.在加氢过程中,Mn₃O₄可以与浆液中ZnSO₄发生化学反应生成一种难溶性的(Zn(OH)₂)₃(ZnSO₄)(H₂O)₃盐.该盐易化学吸附在Ru催化剂表面上,从而在提高Ru催化剂上环己烯选择性起关键作用.当催化剂中Mn含量为5.4%时,环己烯收率为61.3%,同时具有良好的稳定性和重复使用性能.     

由苯制备环己醇新途径

将可溶性Ru纳米粒子用于催化苯选择性加氢制备环己烯反应,考察了还原方法对Ru纳米粒子催化活性的影响;并以醇水还原法制备的Ru纳米粒子为催化剂,考察了温度和压力对反应性能的影响.当使用脱硫的苯作为原料时,苯转化率可达30.2%,环己烯选择性达到46.9%.以无水兰尼镍作催化剂,100oC时,环氧环己烷加氢转化率为100%,环己醇选择性为93.2%.从原料苯出发制得环己醇的单程收率可达14%,由此找到一条制备环己醇的新途径.     

以电化学方法在离子液体[DEME][BF4]中合成铂纳米粒子

通过恒电位电沉积法在离子液体N,N-二乙基-N-甲基-N-（2-甲氧基乙基）铵四氟硼酸铵（[DEME][BF₄]）中,在玻碳电极上制备了铂纳米颗粒。首先探究了不同沉积电势和不同沉积时间对铂纳米粒子微观形貌的影响,由SEM和TEM图发现在-2.5 V下沉积480 s制备的铂纳米粒子的平均粒径约为2.38 nm。使用高分辨率透射电子显微镜（HRTEM）和电子衍射（SAED）对其晶体结构进行表征,证明了铂纳米粒子为面心立方（fcc）晶体结构。在硫酸中测试铂纳米粒子的催化性能,发现其暴露出明显的（110）和（100）晶面。进一步对铂的电沉积行为进行研究发现,Pt（Ⅳ）的两步还原是由扩散过程和电化学过程共同控制。     

以电化学方法在离子液体[DEME][BF4]中合成铂纳米粒子

通过恒电位电沉积法在离子液体N,N-二乙基-N-甲基-N-（2-甲氧基乙基）铵四氟硼酸铵（[DEME][BF₄]）中,在玻碳电极上制备了铂纳米颗粒。首先探究了不同沉积电势和不同沉积时间对铂纳米粒子微观形貌的影响,由SEM和TEM图发现在-2.5 V下沉积480 s制备的铂纳米粒子的平均粒径约为2.38 nm。使用高分辨率透射电子显微镜（HRTEM）和电子衍射（SAED）对其晶体结构进行表征,证明了铂纳米粒子为面心立方（fcc）晶体结构。在硫酸中测试铂纳米粒子的催化性能,发现其暴露出明显的（110）和（100）晶面。进一步对铂的电沉积行为进行研究发现,Pt （Ⅳ）的两步还原是由扩散过程和电化学过程共同控制。     

自旋转换-氧化石墨烯纳米复合材料的制备及磁性

利用氧化石墨烯（GO）表面具有丰富含氧基团的特点,采用原位生长法将经典的亚铁三氮唑自旋转换（SCO）配位聚合物[Fe（Htrz）₂（trz）]（BF₄）负载到二维材料GO的表面。利用X射线粉末衍射（PXRD）、红外光谱（FTIR）、SEM、TEM、拉曼等手段对自旋转换-氧化石墨烯（SCO-GO）纳米复合材料进行了表征。通过光谱表征发现,复合材料的FTIR和PXRD特征峰为GO和[Fe（Htrz）₂（trz）]（BF₄）特征峰的叠加,初步证明了自旋转换-氧化石墨烯纳米复合材料已成功制备。SEM和TEM分析直观地显示立方体状的[Fe（Htrz）₂（trz）]（BF₄）纳米颗粒均匀地分散在氧化石墨烯表面,且随着原位生长时间的增加,GO表面的[Fe（Htrz）₂（trz）]（BF₄）的负载量增加、尺寸增大。拉曼图谱表明[Fe（Htrz）₂（trz）]（BF₄）负载到GO表面后,氧化石墨烯特征拉曼峰的强度比（ID/IG）增大,说明氧化石墨烯的缺陷密集程度增大,[Fe（Htrz）₂（trz）]（BF₄）纳米颗粒与石墨烯之间的作用力增强。磁性测试表明不同自组装时间（1、6、12 h）的SCO-GO复合材料的T_1/2↑分别为381.1、381.5和382.4 K,T_1/2↓分别为345.9、345.0和344.8 K,其磁滞回线宽度分别为35.2、36.5和37.6 K,这是由于不同自组装时间的SCO-GO复合材料中[Fe（Htrz）2（trz）]（BF4）的负载量和尺寸的差异导致的。DSC分析结果和磁性结果一致,证实了SCO-GO复合材料自旋转变温度向高温区移动。     

Ru/Ce(OH)CO3纳米复合材料催化氨硼烷水解产氢

采用一种简单的方法快速合成了Ru/Ce（OH）CO₃纳米复合材料。基于TG,XRD,TEM,EDX,XPS和ICP等方法详细表征了所制备的催化剂,并用于催化氨硼烷水解制氢。表征结果表明尺寸大约为4.8 nm的Ru纳米粒子高度分散在Ce（OH）CO₃纳米棒上。该催化剂对于氨硼烷水解制氢表现出优异的催化性能,在室温下其转化频率（TOF）达到389.6 mol_H2·mol_Ru^-1·min^-1。而且该催化剂循环使用11次之后依然能够对氨硼烷催化产氢保持很高的活性。     

The partial hydrogenation of benzene to cyclohexene by nanoscale ruthenium catalysts in imidazolium ionic liquids

The controlled decomposition of an Ru(0) organometallic precursor dispersed in 1-n-butyl-3-methylimidazolium hexafluorophosphate (BMI.PF(6)), tetrafluoroborate (BMI.BF(4)) or trifluoromethane sulfonate (BMI.CF(3)SO(3)) ionic liquids with H(2) represents a simple and efficient method for the generation of Ru(0) nanoparticles. TEM analysis of these nanoparticles shows the formation of superstructures with diameters of approximately 57 nm that contain dispersed Ru(0) nanoparticles with diameters of 2.6+/-0.4 nm. These nanoparticles dispersed in the ionic liquids are efficient multiphase catalysts for the hydrogenation of alkenes and benzene under mild reaction conditions (4 atm, 75 degrees C). The ternary diagram (benzene/cyclohexene/BMI.PF(6)) indicated a maximum of 1 % cyclohexene concentration in BMI.PF(6), which is attained with 4 % benzene in the ionic phase. This solubility difference in the ionic liquid can be used for the extraction of cyclohexene during benzene hydrogenation by Ru catalysts suspended in BMI.PF(6). Selectivities of up to 39 % in cyclohexene can be attained at very low benzene conversion. Although the maximum yield of 2 % in cyclohexene is too low for technical applications, it represents a rare example of partial hydrogenation of benzene by soluble transition-metal nanoparticles.     

室温离子液体中银纳米微粒的制备与结构表征

利用化学还原方法在室温离子液体1-甲基-3-丁基咪唑四氟硼酸盐中制备了金属银纳米微粒,采用X射线衍射,透射电子显微镜,傅立叶红外光谱和热分析对所制备的样品进行了结构表征.结果表明,所制备的银纳米微粒具有立方相结构,粒径约为20 nm.离子液体不但作为反应的溶剂而且作为修饰剂修饰在银纳米微粒的表面,从而有效地阻止了银纳米微粒的团聚.     

Simple one-step preparation of cerium trifluoride nanoparticles

Cerium trifluoride have great potential in material applications for luminescent materials, composite materials or ionic conductors especially in the form of nanoparticles and nanoobjects. In this work, nanoparticles of CeF₃ were prepared by simple one pot reaction of ionic liquid 1-butyl-3-methylimidazolium hexafluorophosphate (bmimPF₆) with CeO₂ and by reaction of CeO₂ with KPF₆ in ionic liquid 1-butyl-3-methylimidazolium chloride (bmimCl). Prepared nanoparticles were analyzed by XRD and SEM analysis. Average diameter of prepared nanoparticles resulting from Sherrer formula is 12 nm. Nanoparticles did not form ordered agglomerates and could be used in the form of separate nanoparticles which are desired in some applications.     

Nanoscale Ru(0) particles: arene hydrogenation catalysts in imidazolium ionic liquids

The reduction of [Ru(COD)(2-methylallyl) 2] (COD = 1,5-cyclooctadiene) dispersed in various room-temperature ionic liquids (ILs), namely, 1- n-butyl-3-methylimidazolium (BMI) and 1- n-decyl-3-methylimidazolium (DMI), associated with the N-bis(trifluoromethanesulfonyl)imidates (NTf 2) and the corresponding tetrafluoroborates (BF 4) with hydrogen gas (4 bar) at 50 degrees C leads to well-dispersed immobilized nanoparticles. Transmission electron microscopy (TEM) analysis of the particles dispersed in the ionic liquid shows the presence of [Ru(0)] n nanoparticles (Ru-NPs) of 2.1-3.5 nm in diameter. Nanoparticles with a smaller mean diameter were obtained in the ILs containing the less coordinating anion (NTf 2) than that in the tetrafluoroborate analogues. The ruthenium nanoparticles in ionic liquids were used for liquid-liquid biphasic hydrogenation of arenes under mild reaction conditions (50-90 degrees C and 4 bar). The apparent activation energy of E A = 42.0 kJ mol (-1) was estimated for the hydrogenation of toluene in the biphasic liquid-liquid system with Ru-NPs/BMI.NTf 2. TEM analysis of the ionic liquid material after the hydrogenation reactions shows no significant agglomeration of the [Ru(0)] n nanoparticles. The catalyst ionic liquid phase can be reused several times without a significant loss in catalytic activity.     

Synthesis of palladium nanoparticles on organically modified silica: Application to design of a solid-state electrochemiluminescence sensor for highly sensitive determination of imipramine

Organically modified silica substrate containing amine and vinyl functional groups were used for reduction and stabilization of palladium nanoparticles. Uniform spherical nanoparticles of palladium with average diameter of 10 nm were formed on silica substrate by direct contact of the substrate with an aqueous solution of palladium precursor, without the addition of any chemical reducer. Moreover, a sensitive and selective solid state electrochemiluminescence sensor was fabricated for the determination of imipramine, based on Ru(bpy)₃²⁺-palladium nanoparticles doped carbon ionic liquid electrode. In this process, imipramine acts as a co-reactant for Ru(bpy)₃²⁺. It is believed that the enhancement of the electrochemiluminescence signal in the presence of palladium nanoparticles in the composite is due to palladium catalytic effect on electrochemical and also chemical process involved in formation of Ru(byp)₃²⁺*. In addition, the results confirmed that, the rigid composite electrode shows the characteristic of microelectrode arrays. The proposed method was applied to the determination of imipramine in tablets and urine samples. The electrochemiluminescence intensity showed good linearity with the imipramine concentration from 1–100 pM, with a detection limit of 0.1 pM.     

Solvent effect on the synthesis of monodisperse amine-capped Au nanoparticles

A remarkable solvent effect in a single-phase synthesis of monodisperse amine-capped Au nanoparticles is demonstrated.Oleylamine-capped Au nanoparticles were prepared via the reduction of HAuCU by an amine-borane complex in the presence of oleylamine in an organic solvent.When linear or planar hydrocarbon(e.g.,n-hexane,n-octane,1-octadecylene,benzene,and toluene) was used as the solvent, high-quality monodisperse Au nanoparticles with tunable sizes were obtained.However,Au nanoparticles with poor size dispersity were obtained when tetralin,chloroform or cyclohexane was used as the solvent.The revealed solvent effect allows the controlled synthesis of monodisperse Au nanoparticles with tunable size of 3-10 nm.     

Transition-metal nanoparticles in imidazolium ionic liquids: recyclable catalysts for biphasic hydrogenation reactions

1-n-Butyl-3-methylimidazolium hexafluorophosphate room-temperature ionic liquid is not only suitable as a medium for the preparation and stabilization of iridium nanoparticles but also ideal for the generation of recyclable biphasic catalytic systems for hydrogenation reactions. Thus, Ir(0) nanoparticles with a mean diameter of 2 nm have been prepared by reduction of Ir(I) dissolved in the ionic liquid with H2. This catalytic solution can be reused several times for the biphasic hydrogenation of olefins under mild reaction conditions.     

高温液相还原法制备钴纳米晶及其二维有序阵列

由于小尺寸效应,纳米晶具有独特的电、磁、光学和结构性质,因而在材料领域具有广阔的应用前景,例如,利用磁性金属和半导体纳米晶对尺寸敏感的特性进行超高密度信息磁存储及微电子技术的应用研究．但表面原子的巨大剩余成键能力使其倾向于相互团聚并长大,只有实现纳     

Ruthenium nanoparticles polymer-protected on beta zeolite: characterization and catalytic properties in benzene hydrogenation

Summary Ruthenium nanoparticles supported on zeolite Beta catalysts were prepared by alcohol reduction of RuCl₃solution in the presence of PVP. Highly dispersed Ru nanoparticles with mono-size formed on the zeolite surface and their size can be controlled by changing the amount of PVP at same ruthenium loading. In the water/benzene system, Ru-PVP/Beta catalyst for benzene hydrogenation showed high activity, selectivity and good stability.