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.     

过渡金属助剂改性Ca-Zr催化剂上甲醇与碳酸丙烯酯反应制备碳酸二甲酯

采用溶胶凝胶法制备了一系列由过渡金属助剂改性的Ca-Zr催化剂，对其低温下甲醇与碳酸丙烯酯(PC)酯交换反应合成碳酸二甲酯(DMC)的催化性能进行了研究。结果表明，系列过渡金属改性的Ca-Zr催化剂上DMC选择性的顺序依次为Co-Ca-Zr> Cu-Ca-Zr> Ca-Zr> Fe-Ca-Zr> Ni-Ca-Zr> Zn-Ca-Zr。其中，Co改性的Co-Ca-Zr催化剂在35℃、甲醇/PC物质的量比为15及催化剂用量为4%的条件下反应2 h,PC的转化率可达84.3%,DMC的选择性可达94.5%。结合XRD、FT-IR、XPS和CO₂-TPD等表征结果发现，催化剂的碱性位强度增加可以提高PC的转化率，而总碱性位含量提高则降低DMC的选择性。Co改性的Ca-Zr催化剂具有最少的碱性位和最高的强碱性位站比，因而表现出较高的PC转化率和DMC选择性。     

用于甲醇直接气相氧化羰基化的负载铜催化剂

 采用浸渍法制备了负载型铜基催化剂,并用其催化甲醇直接气相氧化羰基化合成碳酸二甲酯(DMC), 考察了浸渍溶剂、载体、助催化剂和铜含量的影响. 结果表明,以CuCl为活性组分原料、浓氨水为浸渍溶剂和活性炭为载体制得的负载铜催化剂显示出很高的催化活性,在特定的反应条件下,该催化剂上甲醇的转化率可达27.7%, DMC选择性可达95%. 分子筛负载的铜催化剂上甲醇的转化率低于1%, 但是生成DMC的选择性高达100%. 催化剂活性随着Cu负载量的增加而增大,但负载量过高可引起甲醇的过度氧化反应,导致DMC选择性下降. 催化剂中添加KOH或钯化合物,有利于提高以CuCl2为活性组分原料制得的铜催化剂的活性,但同时也促进了副反应的发生. 随着反应时间的延长,催化剂的活性组分流失,活性下降,但是生成DMC的选择性维持在95%左右.     

聚离子液体催化碳酸乙烯酯与甲醇的酯交换反应

通过N-乙烯基咪唑鎓离子液体、 丙烯酸钠(NaAA)和交联剂二乙烯基苯(DVB)或1-乙烯基-3-三乙二醇基咪唑溴盐{[(EG)₃-DVIm]Br₂)}自由基聚合合成了一系列含羧酸根的聚离子液体. 将所合成的聚离子液体用于催化甲醇与碳酸乙烯酯(EC)酯交换反应制备碳酸二甲酯(DMC). 研究结果表明, 在甲醇和EC混合溶剂中具有最大溶胀度的聚离子液体催化剂poly[VOIm-AA-DVIm]活性最高. 在优化反应条件[120 ℃, 6 h, 1.0%(摩尔分数)催化剂用量, n(甲醇)/n(EC)=10∶1]下, DMC收率为76.6%, 选择性为90.1%, 达到了与均相催化剂1-丁基-3-甲基咪唑醋酸盐([BMIm]OAc)相当的活性.     

KNO3/AlSBA-15分子筛催化合成碳酸二丙酯的研究

研究了KNO3/AlSBA-15负载型分子筛催化剂用于碳酸二甲酯(DMC)与丙醇的酯交换合成碳酸二丙酯(DPC)反应.分别考察了载体的制备方法,活性组分的负载量,催化剂的活化温度及反应时间等因素对催化活性的影响,研究表明该催化剂对于这一反应具有较高的催化活性.当摩尔比DMC∶丙醇=1∶4,催化剂用量为反应物总质量的3%,反应温度为90℃,反应时间为6h时,DPC的选择性为96.0%,收率为90.2%.     

TiO2-MoO3/SiO2催化碳酸二甲酯与乙酸苯酯酯交换合成碳酸二苯酯

采用分步等体积浸渍法制备了催化剂r%TiO2-q%MoO3/SiO2(1q-r)。以碳酸二甲酯(DMC)与乙酸苯酯(PA)酯交换合成碳酸二苯酯(DPC)为探针反应,考察了1的催化活性。优化反应条件为:PA 290 mmol,n(PA):n(DMC)=2:1,18-4 1.4 g,于180℃反应7 h。在优化反应条件下,DMC转化率77.5%,DPC选择性49.4%,碳酸甲苯酯和DPC的总选择性87.2%。催化剂重复使用时,活性下降很快,也很难通过高温焙烧再生。     

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。     

助剂对合成碳酸二甲酯用活性炭负载Wacker催化剂结构和性能的影响

 以碱金属或碱土金属的盐或氢氧化物为助剂修饰活性炭(AC)负载的Wacker催化剂PdCl2-CuCl2. 甲醇气相氧化羰基化合成碳酸二甲酯(DMC)的反应活性评价结果表明,以乙酸钾(KOAc)为助剂的效果最好. 在KOAc/CuCl2摩尔比为1.0的条件下制备的催化剂用于该合成反应时,DMC的时空产率提高了5倍. XRD,SEM及EPR表征结果显示,在催化剂中加入适量的KOAc,有利于Cu2Cl(OH)3物相在载体表面的形成和分散,从而加快了催化剂活性物种Cu和Pd的氧化还原循环速度.     

在La改性HZSM-5分子筛上甲醇对噻吩转化反应规律的影响

探讨了在HZSM-5(硅铝摩尔比为25)分子筛催化剂上,甲醇对噻吩在固定床微型反应器中催化脱硫转化反应规律的影响.研究结果表明:反应温度只有达到623 K时,噻吩才有较大的转化反应,此时噻吩转化率达到了51%以上;含活性氢物质甲醇的浓度是甲醇与溶剂苯的体积比为1∶2;掺镧的HZSM-5催化剂对噻吩的催化转化有较大的促进作用,掺镧量为1.0%时噻吩的转化率和硫化氢的产率分别达到了51.3%、18.1%,与未掺镧的HZSM-5分子筛催化剂相比,噻吩的转化率和硫化氢的产率分别提高了36.0%、11.9%;质量空速对噻吩催化转化的影响主要体现在影响噻吩在催化床层上的停留时间,质量空速为14.h-1比较合适.     

NaF含量对以水滑石结构为前驱体的固体碱催化剂F-Ca-Mg-Al及碳酸二甲酯合成的影响（英文）

以碳酸丙烯(PC)和甲醇为原料,经酯交换反应合成的多功能、环保的碳酸二甲酯(DMC)是一种绿色、节能的合成方法。CaO固体碱催化剂对该反应具有良好的催化性能,但其再生性不理想。以F-Ca-Mg-Al水滑石(LDHs)为原料,制备了一系列不同Na F用量的固体碱催化剂,并对其进行了表征和酯交换反应测试。与不加氟的FCMA-0催化剂相比,经氟改性后的催化剂的比表面积、碱量、催化活性等性能均有明显提高。催化活性由高到低依次为:FCMA-0.8> FCMA-0.4>FCMA-1.2> FCMA-1.6> FCMA-0,这与总碱位量和强碱位量一致。FCMA-0.8催化剂活性最好,与纯CaO催化剂的相当,PC转化率为66.8%,DMC选择性为97.4%,DMC收率为65.1%。在10次循环使用后,FCMA-0.8催化剂的DMC收率仅下降3.9%(CaO催化剂下降33.2%)。FCMA-0.8在PC与甲醇酯交换制DMC方面具有良好的工业应用前景。     

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.     

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.     

Ni基双金属催化剂加氢脱氧性能的研究

考察了Ni-M/γ-Al2O3（M＝Co、Cu、Fe、La）双金属催化剂对醇、酸、酮有机含氧化合物（丁醇、丁酸、丁酮）的加氢脱氧性能，并对其中间产物进行了考察。通过TPR、XRD表征手段对Ni基催化剂的还原性能、表面分散度等特性进行了研究。结果表明，Ni基催化剂中第二活性组分相对不同有机含氧化合物表现出不同的加氢活性和选择性。对于丁酸，在Ni基催化剂中加入Fe表现出较好的活性；对于丁醇，加入La有较好的加氢脱氧性能；而对于丁酮，加入Cu更有利于提高催化剂的脱除性能。醇和酯是有机酸在Ni/γ-Al2O3催化剂上加氢转化的中间产物。     

助剂对Ni基催化剂结构及甲烷化性能的影响

本文采用等体积浸渍制备了掺杂不同金属助剂改性的Ni基催化剂,考察了其催化浆态床CO甲烷化的性能。通过XRD、H2-TPR、HR-TEM等表征对催化剂进行了分析,结果表明,掺杂Zr、Co、Ce、Zn、La助剂促进了Ni物种在载体表面的分散,减小了Ni的晶粒尺寸,降低了催化剂的还原温度;掺杂Mg助剂则导致催化剂的还原温度升高。浆态床活性评价结果表明,掺杂Zr、Co、Ce、Zn、La助剂提高了催化剂的甲烷化性能,其中以La助剂的效果最明显,通过对La负载量进一步优化后发现,当La负载量为8%时,催化剂的甲烷化催化性能最优,CO转化率、CH4选择性和时空收率分别达到96.3%、87.1%和179.6 g·kg-1·h-1;掺杂Mg助剂则降低了催化剂的甲烷化活性。     

助剂对Ni基催化剂结构及甲烷化性能的影响

本文采用等体积浸渍制备了掺杂不同金属助剂改性的Ni基催化剂,考察了其催化浆态床CO甲烷化的性能。通过XRD、H₂-TPR、HR-TEM等表征对催化剂进行了分析,结果表明,掺杂Zr、Co、Ce、Zn、La助剂促进了Ni物种在载体表面的分散,减小了Ni的晶粒尺寸,降低了催化剂的还原温度;掺杂Mg助剂则导致催化剂的还原温度升高。浆态床活性评价结果表明,掺杂Zr、Co、Ce、Zn、La助剂提高了催化剂的甲烷化性能,其中以La助剂的效果最明显,通过对La负载量进一步优化后发现,当La负载量为8%时,催化剂的甲烷化催化性能最优,CO转化率、CH₄选择性和时空收率分别达到96.3%、87.1%和179.6g·kg^-1·h^-1;掺杂Mg助剂则降低了催化剂的甲烷化活性。     

碱金属沉积对Mn-Ce/TiO_2低温SCR催化剂性能影响

采用溶胶凝胶法制备了Mn-Ce/TiO_2低温SCR催化剂,考察了碱金属浓度与种类对催化剂活性的影响,探究了不同反应条件下钠盐沉积对活性保留分率的影响,利用SEM、BET、XRD和FT-IR对催化剂碱金属中毒原因进行了分析。结果表明,碱金属毒化后催化剂脱硝活性下降,钾中毒催化剂失活程度高于钠中毒的催化剂,2%钾中毒催化剂在160℃时NO去除率为62.0%,较新鲜催化剂下降29.2%。这主要因为碱金属毒化造成催化剂比表面积明显减小,且催化剂载体锐钛矿型TiO_2部分转化为金红石型,BET和SEM表征均说明碱金属沉积堵塞了催化剂表面的微孔。碱金属对Mn-Ce/TiO_2催化剂活性保留分率的影响表明,催化剂的颗粒粒径对其活性保留分率影响不大,碱金属含量减小、温度升高,Mn-Ce/TiO_2催化剂的活性保留分率增加,Na_2SO_4和NaCl对Mn-Ce/TiO_2催化剂的脱硝活性抑制作用大于KNO_3。     

Facile synthesis of poly(ether carbonate)s via copolymerization of CO2 and propylene oxide under combinatorial catalyst of rare earth ternary complex and double metal cyanide complex

Poly(ether carbonate)s (PPCs) with carbonate unit (CU) content ranging from 57.8 to 97.1% and number average molecular weight (M_n) around 100 kg/mol were conveniently prepared via copolymerization of CO₂ and propylene oxide under combinatorial catalyst of rare earth ternary (RET) complex and double metal cyanide (DMC) complex. Enhancement of catalytic activity and reduction of propylene carbonate byproduct were realized due to synergetic effect of the two metal catalysts, where DMC can be activated in the presence of RET. Solubility fractionation confirmed that the obtained PPCs were copolymers, not physical blends of each polymer. Thermal performances of the PPCs were closely related to their CU content, their glass transition temperatures (T_g) were tunable in the range of 6.7–36.3 °C, which decreased with decreasing CU content, while their thermal stabilities were enhanced significantly, an increase of 50.5 °C in 50% weight loss temperature was observed when CU content decreased from 97.1 to 57.8%. Both shear storage modulus and complex viscosity increased with increasing CU content, which became more obvious at lower frequency, featuring well with the CU content in the PPCs. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2012     

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     

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。     

Encapsulation of transition metal catalysts by ligand-template directed assembly

Encapsulated transition metal catalysts are presented that are formed by templated self-assembly processes of simple building blocks such as porphyrins and pyridylphosphine and phosphite ligands, using selective metal-ligand interactions. These ligand assemblies coordinate to transition metals, leading to a new class of transition metal catalysts. The assembled catalyst systems were characterized using NMR and UV-vis spectroscopy and were identified under catalytic conditions using high-pressure infrared spectroscopy. Tris-3-pyridylphosphine binds three mesophenyl zinc(II) porphyrin units and consequently forms an assembly with the phosphorus donor atom completely encapsulated. The encapsulated phosphines lead exclusively to monoligated transition metal complexes, and in the rhodium-catalyzed hydroformylation of 1-octene the encapsulation of the catalysts resulted in a 10-fold increase in activity. In addition, the branched aldehyde was formed preferentially (l/b = 0.6), a selectivity that is highly unusual for this substrate, which is attributed to the encapsulation of the transition metal catalysts. An encapsulated rhodium catalyst based on ruthenium(II) porphyrins and tris-meta-pyridyl phosphine resulted in an even larger selectivity for the branched product (l/b = 0.4). These encapsulated catalysts can be prepared easily, and various template ligands and porphyrins, such as tris-3-pyridyl phosphite and ruthenium(II) porphyrins, have been explored, leading to catalysts with different properties.