亚铁锌双金属氰化络合物固体催化剂催化合成生物柴油

Fe(Ⅱ)-Zn双金属氰化络合物固体催化剂用于一步催化酯交换和酯化反应制备生物柴油,具有易分离、流程简单,不受水毒性影响的优点。将水溶性金属氰化络合物亚铁氰化钾和金属化合物氯化锌反应,并结合有机配体叔丁醇制备了基于亚铁氰化锌的双金属氰化物络合物(DMC)。并研究了DMC固体催化剂催化菜籽油合成生物柴油过程中,助络合剂种类、催化剂用量、反应温度、醇油摩尔比、反应时间、体系中水和脂肪酸含量等因素对反应过程的影响。研究结果表明,在最佳实验条件下,甲酯产率最高可达98%。催化剂可循环使用,6次循环使用后回收率仍达93.45%,适宜工业化生产。     

Synthesis of biodiesel by transition metal doped Fe/Zn double metal cyanide complex catalysts

研究了掺杂过渡金属盐(La、Ce、Zr、Mn)对亚铁锌双金属氰化物(DMC)固体酸催化剂合成生物柴油的影响,并采用XRD、FT-IR、ICP、BET等方法对其进行结构和性能表征.结果表明,1％的镧、铈、锆、锰金属盐对催化剂的活性都有提高,其中,添加1％镧的DMC催化剂活性最高,在醇油摩尔比16∶1,反应温度160℃,催化剂加入量2％条件下,反应7h,脂肪酸甲酯收率达到99.3％.过渡金属盐引入对催化剂的组成没有影响,但使得催化剂更加分散,颗粒粒径更小,比表面积变大,有利于催化剂和反应物的接触,从而提高了催化剂活性.     

Fe-Zn双金属氰化物催化环氧丙烷开环聚合的研究

用Fe Zn双金属氰化物 (DMC)催化剂合成了数均分子量 30 0 0～ 12 0 0 0的聚氧化丙烯二元醇 .着重考察了聚合反应的温度、加料方式等对聚合物分子量及分布的影响 ,并初步探讨了Fe Zn双金属氰化物催化环氧丙烷开环聚合的反应特征 .实验发现 ,采用Fe ZnDMC催化剂 ,聚合物分子量可控 ;在较高温度下聚合所得的聚合物分子量分布呈双峰形 ,显示反应体系中至少存在两类活性中心 ,这可能与催化剂中存在两种价态的络合物有关 ,当降低聚合温度时 ,聚合物分子量分布呈单峰形 ,可能是一类活性中心没有引发 ;实验中还发现单体分批加料时聚合物分子量分布较窄 ,而一步加料法所得聚合物分子量分布则很宽     

双金属氰化物络合物催化环氧烷烃开环聚合的特征

合成了Co Zn双金属氰化物 (DMC)络合物催化剂 ,以X 射线衍射、元素分析、红外光谱等手段进行了表征 ,考察了该催化体系下环氧丙烷开环聚合的反应特性 ,并初步探讨了聚合反应的机理 .研究发现 ,Co Zn双金属氰化物催化剂具有很高的催化活性 ,适合于中高分子量聚醚的合成 ,但是碱性起始剂起阻聚作用 ;在该催化体系下聚合物分子量可控 ,不饱和度很低 (<0 .0 14meq g) ,分批加料聚合所得到的聚合物分子量分布较窄 (Mn Mw <1.4 ) ,而一步加料聚合所得到的聚合物分子量分布变宽 ;1 3C NMR分析表明聚合物主链具有无规立构分布的特点 ,且链节分布几乎都为头 尾方式 .聚合过程中活性链与非活性链之间可能存在一个交换反应 ;虽然聚合反应有终止 ,但与聚合物链长没有关系 ,聚合物链的终止是可逆的 .     

三维异双金属混合桥氰化物的合成和结构

高Tc分子磁体的研究近年来受到重视，其中尤以双过渡金属氰化物的研究发展异常迅猛．继Verdaguer[1]报道了Tc=90K的CsNi[Cr（CN）6]2·H2O配合物后，Verdaguer[2]和Girlami等[3]又分别报道了一系列TC=240、230、190K的同或异双过渡金属含CN配合物．Fujishima等[4]报道的具有磁光效应的K0.2Co1.4[Fe（CN）6]·6.9H2O配合物使分子磁性应用于分子电子学领域成为可能．但上述化合物均为粉末，未能获得其晶体结构，因此无法阐明其磁交换机理，亦难以发展成为晶须及其它异型磁性材料．为弄清混合金属氰化物成键性质、CN桥中介磁交换机…     

无机多核过渡金属氰化物薄膜修饰电极的新进展

本文对普鲁士兰类无机多核过渡金属氰化物薄膜化学修饰电极的近年发展及其在电催化，电色效应，离子选择性电极和生物活体分析等方面的应用进行了评述，引用文献50篇。     

Fe/Zn双金属氰化物催化剂催化环氧丙烷聚合的活性结构研究

以氯化锌、铁氰化钾（含有整合剂）的水溶液为原料，合成了铁锌双金属氰化物（DMC）催化剂。为获得高活性的DMC催化剂，需将叔丁醇 、多元醇螯合剂螯合至其结构中，用XRD、XPS等分析手段，对铁锌DMC催化剂的结构与活性进行分析表征。实验发现，DMC催化剂的晶体结构与螯合剂密切相关，螯合剂能显著降低DMC催化剂的结晶程度，从而提高DMC催化剂的活性。同时，氯化锌过量也有利于DMC催化剂活性的提高。并表征了相关DMC催化剂的活性中心。     

固定化脂肪酶催化合成生物柴油

固定化脂肪酶催化合成生物柴油;转酯反应;固定化脂肪酶;菜籽油;甲醇;生物柴油     

过渡金属催化苯并咪唑衍生物的合成研究进展

苯并咪唑衍生物具有多种生物活性,在医药、农药等领域有着广泛的应用,该类化合物的合成也是当前的研究热点之一.过渡金属催化苯并咪唑的合成方法具有简单、直接、高效等优点,近年来发展迅速,寻找更简单、高效、廉价、环保的催化体系,一直是化学工作者研究的目标.本文综述了当前报道较多的几种过渡金属催化合成苯并咪唑新方法的研究进展,并简要介绍了各类催化体系的优缺点.     

过渡金属催化合成硫醚的研究进展

硫醚基团广泛存在于天然产物和药物中,独特的分子结构使其具有较高的生物活性,常被用于药物、电化学材料和香料香精的合成。过渡金属催化的C-S键偶联反应因具有操作简单、高效廉价、反应条件温和等优点而成为合成硫醚化合物的主要方法之一。本文重点从有机硫源和无机硫源两方面,对近年来过渡金属催化合成硫醚的研究进行了综述。     

Fe/Zn double metal cyanide catalyzed ring-opening polymerization of propylene oxide: 2. Characterization of active structure of double metal cyanide catalysts

Double metal cyanide (DMC) complexes based on Zn₃[Fe(CN)₆]₂ were synthesized using different molar ratios of ZnCl₂ to K₃[Fe(CN)₆] and special complexing agents. IR spectroscopy, electron spectroscopy for chemical analysis, X-ray diffraction, scanning electron microscopy, X-ray photoelectron spectroscopy, and other analytical techniques were employed to characterize these catalysts. The morphology and structure of these DMC catalysts were attributed to the different complexing agents as well as to the different molar ratios of ZnCl₂ to K₃[Fe(CN)₆]. In addition, the catalytic activity was strongly correlated with the morphology and noncrystalline content of DMC catalysts. High-activity catalysts could be prepared by controlling the structure of DMC catalysts by incorporating complexing agents. The active species of DMC catalysts for ring-opening polymerization are Zn²⁺, [Fe(CN)₆]^3–, Cl^–, and the compound of their ligands.     

Ring‐opening polymerizations of propylene oxide by double metal cyanide catalysts prepared with ZnX2 (X = F,Cl, Br,or I)

Polymerizations of propylene oxide were carried out with double metal cyanide (DMC) catalysts based on Zn₃[Co(CN)₆]₂. Through the control of the type and amount of ZnX₂ (X = F, Cl, Br, or I) during the preparation of the catalyst, the catalytic activity, induction period, and unsaturation level in the polyether polyols could be tuned. The DMC catalysts were characterized by X‐ray photoelectron spectroscopy, infrared spectroscopy, and X‐ray powder diffraction. In general, ZnBr₂ was the most effective zinc halide with respect to the properties of the resulting polymers as well as the activity and induction period. The average rates of polymerizations of DMC catalysts prepared with ZnCl₂, ZnBr₂, and ZnI₂ were 889, 1667, and 784 g of polyoxypropylene/g of catalyst h, respectively, with induction periods of about 53, 5, and 60 min, respectively, at 115 °C. The DMC catalysts produced polyoxypropylenes with an ultralow unsaturation level (0.0025–0.0057 mequiv/g) and a narrow molecular weight distribution (1.07–1.42) without high‐molecular‐weight tails; this resulted in a low viscosity (962–3950 cP). According to the results collected from catalyst characterizations and polymerizations, the active sites of DMC‐catalyzed polymerization had mainly coordinative characters. The presence of free anions accelerated the ring‐opening procedure and thus enhanced the propagation rate and shortened the induction period. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 4393–4404, 2005     

Alternating copolymerization of carbon dioxide and cyclohexene oxide catalyzed by silicon dioxide/Zn?CoIII double metal cyanide complex hybrid catalysts with a nanolamellar structure

Air‐stable hybrid catalysts of silicon dioxide/double metal cyanide complexes (Si‐DMCCs) based on Zn₃[Co(CN)₆]₂ (ZHCC) were prepared by an in situ sol–gel method. The Si‐DMCCs showed low crystallinity and a nanolamellar structure with a thickness of ～40–60 nm. In particular, a lamellar structure of regular hexagonal shape was observed for Si‐DMCCs with low SiO₂ content. These catalysts had very high catalytic activity for alternating copolymerization of cyclohexene oxide (CHO) and carbon dioxide. A turnover number of 11,444, turnover frequency of 3815 h^?1, and apparent efficiency of 7.5 kg polymer/g ZHCC (～24.0 kg polymer/g Zn) were achieved at 3.8 MPa and 100 °C. The poly(cyclohexenylene carbonate) (PCHC) polymers obtained were completely atactic with a molecular weight (M_n) of ～10 kg/mol and polydispersity of 2.0–3.0. The PCHCs had a structure of nearly alternating CHO and CO₂ units, with a molar fraction of carbonate units of 0.44–0.47. Preliminary investigations of the mechanism suggest that nucleophilic attack by neighboring oxygen atoms is involved in copolymerization initiation with Zn? Co^III DMCCs. © 2008 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 46: 3128–3139, 2008     

Mechanistic insight into initiation and chain transfer reaction of CO2/cyclohexene oxide copolymerization catalyzed by zinc?cobalt double metal cyanide complex catalysts

Although zinc? cobalt (III) double metal cyanide complex (Zn? Co (III) DMCC) catalyst is a highly active and selective catalyst for carbon dioxide (CO₂)/cyclohexene oxide (CHO) copolymerization, the structure of the resultant copolymer is poorly understood and the catalytic mechanism is still unclear. Combining the results of kinetic study and electrospray ionization‐mass spectrometry (ESI‐MS) spectra for CO₂/CHO copolymerization catalyzed by Zn? Co (III) DMCC catalyst, we disclosed that (1) the short ether units were mainly generated at the early stage of the copolymerization, and were hence in the “head” of the copolymer and (2) all resultant PCHCs presented two end hydroxyl (? OH) groups. One end ? OH group came from the initiation of zinc? hydroxide (Zn? OH) bond and the other end ? OH group was produced by the chain transfer reaction of propagating chain to H₂O (or free copolymer). Adding t‐BuOH (CHO: t‐BuOH = 2:1, v/v) to the reaction system led to the production of fully alternating PCHCs and new active site of Zn? Ot‐Bu, which was proved by the observation of PCHCs with one end ? Ot‐Bu (and ? OCOOt‐Bu) group from ESI‐MS and ¹³C NMR spectra. Moreover, Zn?OH bond in Zn? Co (III) DMCC catalyst was also characterized by the combined results from FT‐IR, TGA and elemental analysis. This work provided new evidences that CO₂/CHO copolymerization was initiated by metal? OH bond. © 2012 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2012     

Controlled ring‐opening polymerization of propylene oxide catalyzed by double metal‐cyanide complex

A double metal‐cyanide catalyst based on Zn₃[Co(CN)₆]₂ was prepared. This catalyst is very effective for the ring‐opening polymerization of propylene oxide. Polyether polyols of moderate molecular weight having low unsaturation (<0.015 meq/g) can be prepared under mild conditions. The molecular weight of polymer is entirely controlled by a reacted monomer‐to‐initiator ratio. The polymers prepared with stepwise addition of monomer exhibit a narrower molecular weight distribution as compared with those prepared with one‐step addition of monomer. Various compounds containing active hydrogen, except basic compounds and low‐carbon carboxylic acid, may be used as initiators. The reaction rate increases with increasing catalyst amount and decreases with rising initiator concentration. Polymerization involves a rapid exchange reaction between the active species and the dormant species. It was also proven that, to a certain extent, the chain termination of this catalytic system is reversible or temporary. ¹³C NMR analysis showed that the polymer has a random distribution of the configurational sequences and head‐to‐tail regiosequence. It is assumed that the polymerization proceeds via a cationic coordination mechanism. © 2002 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 40: 1142–1150, 2002     

Polymerization of 1-methoxy-1-ethynylcyclohexane by transition metal catalysts

The polymerization of 1-methoxy-1-ethynylcyclohexane (MEC) was carried out by various transition metal catalysts. The catalysts MoCl₅, MoCl₄, and WCl₆ gave a relatively low yield of polymer (≤ 16%). The catalytic activity of Mo-based chloride catalyst was greater than that of W-based chloride catalyst. However, catalyst tungsten carbene complex (I) gave a larger molar mass and higher yield in the presence of a Lewis acid such as AlCl₃ than in the absence of a Lewis acid. The activity of the tungsten carbene complex was obviously affected by Lewis acidity. The catalyst PdCl₂ was a very effective catalyst for the present polymerization and gave polymers in a high yield. The structure of the resulting poly(MEC) was identified by various instrumental methods as a conjugated polyene structure having an α-methoxycyclohexyl substituent. The poly(MEC)s were mostly light-brown powders and completely soluble in various organic solvents such as tetrahydrofuran (THF), chloroform (CHCl₃), ethylacetate, n-butylacetate, dimethylformamide, benzene, xylene, dimethylacetamide, 1,4-dioxane, pyridine, and 1-methyl-2-pyrrolidinone. Thermogravimetric analysis showed that the polymer started to lose mass at 125°C and that maximum decomposition occurred at 418°C. The x-ray diffraction diagram shows that poly(MEC) has an amorphous structure. © 1997 John Wiley & Sons, Inc.     

冠醚络合高活性双金属氰化物制备及CO2与环氧丙烷共聚

首次在共沉淀过程中添加18-冠-6醚络合生成的钾离子得到了均一的高活性冠醚络合的锌-钴双金属催化剂,并用红外光谱(FTIR)、扫描电镜(SEM)、热重红外(TGA-IR)和X射线衍射(XRD)进行了表征.元素分析发现K含量为1.2%. FTIR表明未加冠醚络合的双金属催化剂离心后上下部分呈现不同的络合状态,而冠醚络合的双金属催化剂仍保持均一. SEM表明冠醚络合的双金属催化剂为均一松散的结构.由于生成的钾离子被冠醚络合,不影响聚合反应效果. TGA-IR表明冠醚不仅络合K离子,还参与对金属活性中心的络合. XRD表明此催化剂具有低的结晶度.所制冠醚络合的锌-钴双金属催化剂能成功催化CO2与环氧丙烷共聚,其中CDMC3催化得到的共聚物碳酸酯含量为47.8%,副产物环状碳酸酯为1.5%,催化效率高达5122 g/g催化剂(32600 g/g Zn),明显优于不添加冠醚以同样工艺制备的DMC1(共聚物碳酸酯含量29.2%,副产物环状碳酸酯3.3%,催化效率4100 g/g催化剂(16300 g/g Zn).与不添加冠醚8次洗涤离心得到的DMC2相当(共聚物碳酸酯含量48.3%,副产物环状碳酸酯含量2.4%,催化效率5073 g/g催化剂(16400 g/g Zn)).基于此结果提出了两步的反应机理假设.     

Highly active double metal cyanide complexes： Effect of central metal and ligand on reaction of epoxide/CO2

Various novel double metal cyanide (DMC) catalysts were successfully prepared by modifying the central metal (M) and one of cyanide ion (CN-) in Zna[M(CN)b]c complex. Such modifications have significant impact on the catalytic efficiency as well as the polymer selectivity for the reaction of PO/CO2. Zn–Ni(Ⅱ) DMC is a potential catalyst for alternating copolymerization of PO/CO2, and DMC catalysts based on Zn3[Co(CN)5X]2 (X = Br-and N3-) exhibit moderate efficiency for the production of polycarbonates. This research presents the preliminary exploration of novel DMC complex via chemical modification of its central metal and ligand.