微量吸附量热技术在NH2-SBA-15合成中的应用

采用共价接枝法, 以氨丙基-三乙氧基硅烷为氨源, 制备了一系列的NH2-SBA-15催化剂, 通过微量吸附量热技术定量地分析了该催化剂表面碱性中心的强度、数量和分布状态. 实验结果表明, SBA-15在 550 ℃焙烧6 h, 氨基硅源与SBA-15质量比为1.5, 是合成NH2-SBA-15催化剂最适宜的条件. 运用微量吸附量热技术实现了对NH2-SBA-15催化剂合成条件的优化.     

介孔Ru-PPh2-KIT-6催化剂应用于水相中烯丙醇异构化的研究

以2-(二苯基膦)乙基三乙氧基硅烷和正硅酸乙酯为混合硅源,运用延时共缩聚法制备带有二苯基膦(PPh2-)修饰配体的KIT-6型介孔氧化硅材料,通过络合Ru(II)获得固载化Ru(II)有机金属催化剂(Ru-PPh2-KIT-6),该催化剂具有规整介孔结构.在水相烯丙醇异构化反应中显示高活性和高选择性,催化性能接近均相催化剂,活性相与载体结合牢固,能够重复使用5次以上.     

外表面钝化SBA-15固载奎宁催化不对称Michael加成反应

以聚环氧乙烷-聚环氧丙烷-聚环氧乙烷三嵌段共聚物(P123)为模板剂制备SBA-15分子筛,将未除模板剂的SBA-15用三甲基氯硅烷钝化后固载奎宁制得外表面钝化CH_3-SBA-15-QN非均相催化剂.对非均相催化剂进行XRD、FT-IR、N_2吸附-脱附表征.并以查尔酮类化合物与丙二腈的不对称Michael加成反应为模型来考察非均相催化剂CH_3-SBA-15-QN的催化活性,实验结果表明,非均相催化剂CH_3-SBA-15-QN比SBA-15-QN催化剂对产物表现出较高的对映选择性.4-甲氧基查耳酮为底物时,CH_3-SBA-15-QN为催化剂时,产物对映选择性能够达到77%,甚至比均相催化剂高6%,充分发挥了载体孔道效应和手性催化剂的不对称诱导能力.     

预处理方法对Ru/SBA-15催化丙三醇氢解反应性能的影响(英)

使用浸渍法结合不同预处理方法制备了一系列的Ru/SBA-15催化剂,并将其应用于丙三醇氢解反应中.使用N_2吸附-脱附、X射线衍射、CO化学吸附以及透射电子显微镜等方法对所制备Ru/SBA-15进行了表征.结果表明,催化剂前驱体经过空气焙烧后再经H_2还原的Ru/SBA-15催化剂上Ru的分散度较低,而直接使用H_2处理较高.同时,随着H_2还原温度提高,Ru分散度逐渐降低.保持反应活性接近时,随着Ru分散度的降低,TOF增加.表明Ru/SBA-15催化剂上丙三醇氢解是结构敏感反应.     

预处理方法对Ru/SBA-15催化丙三醇氢解反应性能的影响(英)

使用浸渍法结合不同预处理方法制备了一系列的Ru/SBA-15催化剂,并将其应用于丙三醇氢解反应中.使用N₂吸附-脱附、X射线衍射、CO化学吸附以及透射电子显微镜等方法对所制备Ru/SBA-15进行了表征.结果表明,催化剂前驱体经过空气焙烧后再经H₂还原的Ru/SBA-15催化剂上Ru的分散度较低,而直接使用H₂处理较高.同时,随着H₂还原温度提高,Ru分散度逐渐降低.保持反应活性接近时,随着Ru分散度的降低,TOF增加.表明Ru/SBA-15催化剂上丙三醇氢解是结构敏感反应.     

催化苯羟基化反应的高效介孔VOx/SBA-16催化剂

利用浸渍法制备了介孔SBA-16负载高分散氧化钒催化剂(VOx/SBA-16),并使用XRD,TEM,N2物理吸附和Raman光谱对其进行了表征.结果表明,制备的VOx/SBA-16催化剂保持了SBA-16立方笼状孔结构,钒物种主要高度分散在SBA-16载体孔内.钒含量为7·3%的VOx/SBA-16催化剂在催化苯羟基化反应中表现出优异的催化性能.这是由于催化剂表面形成了高分散的VO4物种和纳米结构V2O5微晶.     

氨基功能化SBA-15介孔分子筛的制备与表征

以3-氨丙基三乙氧基硅烷为偶联剂,采用后合成法对介孔分子筛(SBA-15)的表面进行改性,制得氨基功能化的介孔NH<,2>-SBA-15材料(简称NH<,2>-SBA-15),其结构和性能经FT-IR,元素分析,XRD,SEM及低温N<,2>吸附-脱附表征.结果表明,氨基成功地嫁接到SBA-15表面,含量高达3.47 ...     

TiO_2-SBA-15催化剂的制备、表征及光催化降解甲基橙

以钛酸四丁酯为钛源,以介孔分子筛SBA-15为载体,采用简单的方法制备TiO2-SBA-15催化剂,并采用FT-IR,XRD和N2吸附-脱附等方法对其进行表征.另外,将制备的TiO2-SBA-15催化剂应用于光催化降解甲基橙溶液,并讨论了钛含量、甲基橙浓度及溶液pH值对降解率的影响.结果表明:在钛酸四丁酯起始加入量为3.2mL,甲基橙浓度为10mg/L,溶液pH=3的条件下,TiO2-SBA-15光催化降解甲基橙的降解率可达到100%.     

负载型TiO2/SBA-15的制备及其光催化还原CO2性能

以羧基改性的SBA-15(COOH/SBA-15)和钛酸四丁酯(TB)为原料,利用COOH/SBA-15表面上高分散的大量羧基将TB锚定,通过溶剂热处理得到高分散负载型TiO2/SBA-15催化剂.产物经XRD,Raman,FT-IR,TEM,N2吸脱附和UV-Vis表征,结果显示:所制备的TiO2/SBA-15催化剂为比表面大、结晶度较高的锐钛矿TiO2,TiO2均匀分散于SBA-15表面,此外,COOH/SBA-15有效抑制了TiO2晶粒的长大.以光催化还原CO2为探针反应,考察了TiO2/SBA-15催化剂在紫外光照射下的光催化性能.结果表明:相比于后处理浸渍法制备的光催化剂,本文制备的TiO2/SBA-15催化剂表现出了高的光催化还原CO2活性,主要产物为甲醇,且TiO2最佳负载量为16.5%,并对相关反应机理做了探讨.     

二氧化硅固载Ru基催化剂上二氧化碳加氢合成甲酸的研究(III): 配体对催化剂反应性能的影响

考察了不同配体对原位合成的固载Ru基催化剂上CO2加氢合成HCOOH反应活性的影响,对于以单齿三苯基类ZPh3分子为配体的催化剂,活性大小顺序为:PPh3>AsPh3>NPh3.以PPh3为配体时,其相应的原位合成催化剂上HCOOH的TOF值为656h-1.其次,双齿膦配体的使用能带来比单齿膦配体更高的活性.以dppe[1,2-双(二苯基膦基)乙烷]为配体时,其相应的原位合成催化剂上HCOOH的TOF值为1190h-1.量子化学的理论计算结果表明,具有适中的σ给予性和π接受性,较小的空间位阻,较好的电子离域作用的PPh3配体性能优于其它单齿三苯基类配体.而具有较好的电子离域作用,并且有螯合作用的双齿膦配体性能优于单齿膦配体.     

Homoallylic alcohol isomerization in water over an immobilized Ru(II) organometallic catalyst with mesoporous structure

PPh(2)-functionalized SBA-15 was synthesized by co-condensation of tetraethyl orthosilicate and 2-(diphenylphosphino)ethyltriethoxysilane through prehydrolysis. The as-prepared PPh(2)-SBA-15 was used as the support to immobilize the Ru(II) organometallic catalyst through the strong coordination between the Ru(II) and the PPh(2)-ligand (Ru-PPh(2)-SBA-15). During 1-phenyl-3-buten-1-ol isomerization carried out in water as an environmentally friendly medium, the Ru-PPh(2)-SBA-15 catalyst exhibited almost the same activity and selectivity as the corresponding RuCl(2)(PPh(3))(3) homogeneous catalyst and could be used repetitively nearly 7 times. On the basis of various characterizations, the correlation of the catalytic behaviors of the Ru-PPh(2)-SBA-15 to its structural characteristics was discussed briefly. Obviously, the high activity of the Ru-PPh(2)-SBA-15 could be attributed to both the high surface area of the support, which ensured the good dispersion of Ru(II) active sites, and the ordered mesoporous structure, which facilitated the diffusion of organic reactants.     

苯乙烯-丁二烯-苯乙烯三嵌段共聚物新型加氢催化剂的研究

烯烃加氢得到烷烃,从化学热力学角度判断这个反应可以进行,由于氢分子相当稳定,ＨＨ键不易受极化的影响而断裂,实际上,如果没有催化剂的存在,反应是很难进行的．各种过渡金属,例如铂、钯、铑、钴、铱和镍等都具有未充满和不稳定的ｄ电子轨道,容易吸附大量的氢并使其活化,从而很容易对许多基团进行氢化反应．钌／二烯烃／氢气反应体系就符合上述原理,苯乙烯丁二烯苯乙烯三嵌段共聚物（ＳＢＳ）就属二烯烃类共聚物,由于这类共聚物中存在ＣＣ不饱和双键,在日光、紫外光、热等环境下,其耐侯性和热稳定性不好,限制了它在更广泛…     

New benzo[h]quinoline-based ligands and their pincer Ru and Os complexes for efficient catalytic transfer hydrogenation of carbonyl compounds

New benzo[h]quinoline ligands (HCN'N) containing a CHRNH2 (R=H (a), Me (b), tBu (c)) function in the 2-position were prepared starting from benzo[h]quinoline N-oxide (in the case of ligand a) and 2-chlorobenzo[h]quinoline (for ligands b and c). These compounds were used to prepare ruthenium and osmium complexes, which are excellent catalysts for the transfer hydrogenation (TH) of ketones. The reaction of a with [RuCl2(PPh3)3] in 2-propanol at reflux afforded the terdentate CN'N complex [RuCl(CN'N)(PPh3)2] (1), whereas the complexes [RuCl(CN'N)(dppb)] (2-4; dppb=Ph2P(CH2)4PPh2) were obtained from [RuCl2(PPh3)(dppb)] with a-c, respectively. Employment of (R,S)-Josiphos, (S,R)-Josiphos*, (S,S)-Skewphos, and (S)-MeO-Biphep in combination with [RuCl2(PPh3)3] and ligand a gave the chiral derivatives [RuCl(CN'N)(PP)] (5-8). The osmium complex [OsCl(CN'N)(dppb)] (12) was prepared by treatment of [OsCl2(PPh3)3] with dppb and ligand a. Reaction of the chloride 2 and 12 with NaOiPr in 2-propanol/toluene afforded the hydride complexes [MH(CN'N)(dppb)] (M=Ru 10, Os 14), through elimination of acetone from [M(OiPr)(CN'N)(dppb)] (M=Ru 9, Os 13). The species 9 and 13 easily reacted with 4,4'-difluorobenzophenone, via 10 and 14, respectively, affording the corresponding isolable alkoxides [M(OR)(CN'N)(dppb)] (M=Ru 11, Os 15). The complexes [MX(CN'N)(P2)] (1-15) (M=Ru, Os; X=Cl, H, OR; P=PPh3 and P2=diphosphane) are efficient catalysts for the TH of carbonyl compounds with 2-propanol in the presence of NaOiPr (2 mol %). Turnover frequency (TOF) values up to 1.8x10(6) h(-1) have been achieved using 0.02-0.001 mol % of catalyst. Much the same activity has been observed for the Ru--Cl, --H, --OR, and the Os--Cl derivatives, whereas the Os--H and Os--OR derivatives display significantly lower activity on account of their high oxygen sensitivity. The chiral Ru complexes 5-8 catalyze the asymmetric TH of methyl-aryl ketones with TOF approximately 10(5) h(-1) at 60 degrees C, up to 97 % enatiomeric excess (ee) and remarkably high productivity (0.005 mol % catalyst loading). High catalytic activity (TOF up to 2.2x10(5) h(-1)) and enantioselectivity (up to 98 % ee) have also been achieved with the in-situ-generated catalysts prepared from [MCl2(PPh3)3], (S,R)-Josiphos or (S,R)-Josiphos*, and the benzo[h]quinoline ligands a-c.     

Synthesis of ruthenium/reduced graphene oxide composites and application for the selective hydrogenation of halonitroaromatics

Reduced graphene oxide （RGO） supported ruthenium （Ru） catalyst was prepared by an impregnation method using RuCI3 as a precursor and RGO as a support. The catalyst Ru/RGO was used for the selective hydrogenation ofp-chloronitrobenzene （p-CNB） to p-chloroaniline （p-CAN）, showing a selectivity of 96% at complete conversion of p-CNB at 60 ℃ and 3.0 MPa H2. The Ru/RGO catalyst was extremely active for the hydrogenation of a series of nitroarenes, which can be attributed to the small sized and the fine dispersity of the Ru nanoparticles on the RGO sheets characterized by TEM. Moreover, the catalyst also can be recycled five times without the loss of activity.     

Ruthenium(II) polypyridyl complexes: potential precursors, metalloligands, and topo II inhibitors

Neutral and cationic mononuclear complexes containing both group 15 and polypyridyl ligands [Ru(kappa3-tptz)(PPh3)Cl2] [1; tptz=2,4,6-tris(2-pyridyl)-1,3,5-triazine], [Ru(kappa3-tptz)(kappa2-dppm)Cl]BF4 [2; dppm=bis(diphenylphosphino)methane], [Ru(kappa3-tptz)(PPh3)(pa)]Cl (3; pa=phenylalanine), [Ru(kappa3-tptz)(PPh3)(dtc)]Cl (4; dtc=diethyldithiocarbamate), [Ru(kappa3-tptz)(PPh3)(SCN)2] (5) and [Ru(kappa3-tptz)(PPh3)(N3)2] (6) have been synthesized. Complex 1 has been used as a metalloligand in the synthesis of homo- and heterodinuclear complexes [Cl2(PPh3)Ru(micro-tptz)Ru(eta6-C6H6)Cl]BF4 (7), [Cl2(PPh3)Ru(mu-tptz)Ru(eta6-C10H14)Cl]PF6 (8), and [Cl2(PPh3)Ru(micro-tptz)Rh(eta5-C5Me5)Cl]BF4 (9). Complexes 7-9 present examples of homo- and heterodinuclear complexes in which a typical organometallic moiety [(eta6-C6H6)RuCl]+, [(eta6-C10H14)RuCl]+, or [(eta5-C5Me5)RhCl]+ is bonded to a ruthenium(II) polypyridine moiety. The complexes have been fully characterized by elemental analyses, fast-atom-bombardment mass spectroscopy, NMR (1H and 31P), and electronic spectral studies. Molecular structures of 1-3, 8, and 9 have been determined by single-crystal X-ray diffraction analyses. Complex 1 functions as a good precursor in the synthesis of other ruthenium(II) complexes and as a metalloligand. All of the complexes under study exhibit inhibitory effects on the Topoisomerase II-DNA activity of filarial parasite Setaria cervi and beta-hematin/hemozoin formation in the presence of Plasmodium yoelii lysate.     

Bridging fluorides and hard/soft mismatch in d6 and d8 complexes: the case of [Tl(mu-F)3Ru(PPh3)3

[RuCl2(PPh3)3] reacts with thallium(I) fluoride to give either [Tl(mu-F)3Ru(PPh3)3] (1) or [Tl(mu3-F)(mu2-Cl)2Ru2(mu2-Cl)(mu2-F)(PPh3)4] (2) depending on the excess of TlF used. Both 1 and 2 were fully characterized, including X-ray structure determinations. Complex 1 reacts with dihydrogen to form the known ruthenium hydride complex [Ru(H)2(H2)(PPh3)3] upon hydrogenolysis of the Ru-F bond. The reaction of 1 with activated alkyl bromides (R-Br) gives the corresponding alkyl fluorides and the trinuclear complex [Tl(mu3-F)(mu2-F)(mu2-X)Ru2(mu2-Br)(mu2-F)(PPh3)4] (X=Br, F) (3), whose structure closely resembles that of 2. However, 1 is not active as catalyst for the nucleophilic fluorination of R-Br in the presence of thallium fluoride. The effect of the bridging coordination mode of fluoride on the Ru-F bond is discussed in terms of the HSAB principle, which suggests a more general model for predicting the stability of d6 and d8 complexes containing hard ligands (such as fluoro, oxo, and amido).     

New approach to Ru(II) pincer ligand chemistry. Bis(tert-butylaminomethyl)pyridine coordinated to ruthenium(II)

Reaction of 2,6-bis-(tBuNHCH2)2NC5H3 ("N2py") with RuCl2(PPh3)3 gives two isomers of Ru(N2py)Cl2(PPh3), 5, while reaction with RuCl2(DMSO)4 (DMSO = Me2SO) gives isomerically pure Ru(N2py)Cl2(DMSO), whose structure is reported. The PPh3 of 5 can be replaced by CO, P(OPh)3, or pyridine. The chlorides in Ru(N2py)Cl2(CO) can both be replaced by F3CSO3-. Isomer structure preferences are discussed, and the reaction of Ru(N2py)Cl2(pyridine) with O2 gives apparent oxidation of N2py to give the diimine.     

Characterization of Five-Coordinate Ruthenium(II) Phosphine Complexes by X-ray Diffraction and Solid-State (31)P CP/MAS NMR Studies and Their Reactivity with Sulfoxides and Thioethers

31P CP/MAS NMR spectroscopy is examined as a method of characterization for ruthenium(II) phosphine complexes in the solid state, and the results are compared with X-ray crystallographic data determined for RuCl(2)(dppb)(PPh(3)) (dppb = Ph(2)P(CH(2))(4)PPh(2)), RuBr(2)(PPh(3))(3), and the previously determined RuCl(2)(PPh(3))(3). Crystals of RuBr(2)(PPh(3))(3) (C(54)H(45)Br(2)P(3)Ru) are monoclinic, space group P2(1)/a, with a = 12.482(4) ?, b = 20.206(6) ?, c = 17.956(3) ?, beta = 90.40(2) degrees, and Z = 4, and those of RuCl(2)(dppb)(PPh(3)) (C(46)H(43)Cl(2)P(3)Ru) are also monoclinic, space group P2(1)/n, with a = 10.885(2) ?, b = 20.477(1) ?, c = 18.292(2) ?, beta = 99.979(9) degrees, and Z = 4. The structure of RuBr(2)(PPh(3))(3) was solved by direct methods, and that of RuCl(2)(dppb)(PPh(3)) was solved by the Patterson method. The structures were refined by full-matrix least-squares procedures to R = 0.048 and 0.031 (R(w) = 0.046 and 0.032) for 5069 and 5925 reflections with I >/= 3sigma(I), respectively. Synthetic routes to RuBr(2)(dppb)(PPh(3)) and [RuBr(dppb)](2)(&mgr;(2)-dppb) are reported. The reactivity of RuCl(2)(dppb)(PPh(3)) with the neutral two-electron donor ligands (L) dimethyl sulfoxide, tetramethylene sulfoxide, tetrahydrothiophene, and dimethyl sulfide to give [(L)(dppb)Ru(&mgr;-Cl)(3)RuCl(dppb)] is discussed.     

Ru-B/SiO2非晶态催化剂应用于液相葡萄糖加氢制山梨醇

 采用浸渍法结合KBH4还原法制备了Ru-B/SiO2非晶态催化剂(3.14%Ru),并将其用于液相葡萄糖加氢制山梨醇反应. 结果表明,该催化剂具有良好的热稳定性,且其催化活性远高于Raney Ni和Ni-B/SiO2非晶态催化剂,山梨醇的选择性接近于100%,显示出良好的工业化应用前景. 通过与晶态Ru-B/SiO2及Ru/SiO2的催化活性进行比较,并结合ICP,XRD,DSC,SEM,XPS及氢吸附等表征结果,初步讨论了非晶态合金结构和表面电子态对催化剂活性的促进作用.