重铬酸钾氧化法合成2-吡啶甲酸的研究

研究了以2-甲基吡啶为原料,以重铬酸钾为氧化剂,利用化学氧化法合成2-吡啶甲酸的反应条件.考察了反应温度、反应物2-甲基吡啶的浓度和与重铬酸钾的浓度比例、硫酸浓度和反应时间对产率、转化率及选择性的影响,其产物用红外、元素分析和熔点分析表征.实验表明,最佳反应条件:反应温度105℃,2-甲基吡啶摩尔浓度为0.075mol/L,重铬酸钾与2-甲基吡啶浓度比为2∶1,硫酸浓度为9 mol/L,反应时间为2 h,其转化率可达97.6%,2-吡啶甲酸的色谱产率可达87.7%,选择性为89.8%.     

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。     

Co-MCM-41催化氧化二苯甲烷制备二苯甲酮的反应条件

系统地研究了Co掺杂MCM-41用于液相催化氧化二苯甲烷的反应,并探讨了不同溶剂及溶剂用量、反应时间、反应温度、催化剂用量等对二苯甲烷氧化反应的影响;并得出较优的反应条件:m(二苯甲烷)∶m(催化剂)=10∶1;V(二苯甲烷)∶V(冰醋酸)=1∶10;温度为100℃,时间为10 h,二苯甲烷的转化率21%,二苯甲酮的选择性95.8%。     

电氧化合成2-吡啶甲酸

以2-甲基吡啶为原料,用电化学方法合成了2-吡啶甲酸.研究了反应温度、硫酸浓度、反应物2-甲基吡啶浓度和阳极电位对选择性和电流效率的影响.结果表明,在最佳反应条件下,以电化学方法合成2-吡啶甲酸的选择性高达95.3%,电流效率可达到45.3%.     

H3PW6Mo6O40/SiO2催化合成7-羟基-4-甲基香豆素

采用溶胶-凝胶法制备了二氧化硅负载磷钨钼杂多酸催化剂H3PW6Mo6O40/SiO2,该催化剂制备的适宜条件是:m(H3PW6Mo6O40)∶m(SiO2)=40%,煅烧温度150℃,活化时间3 h。以二氧化硅负载磷钨钼酸为催化剂,在无溶剂条件下由间苯二酚和乙酰乙酸乙酯为原料进行Pechmann反应合成7-羟基-4-甲基香豆素。考察了反应物间苯二酚与乙酰乙酸乙酯摩尔比,催化剂用量,反应温度,反应时间等因素对收率的影响,并对反应条件进行优化。结果表明,在间苯二酚与乙酰乙酸乙酯的摩尔比为1∶1.5(其中间苯二酚为0.1mol),反应时间为16 h,H3PW6Mo6O40/SiO2的用量为1.3 g,在油浴加热120℃左右的优化条件下,7-羟基-4-甲基香豆素的收率可达86.1%。     

CeO2改性Ag-V2O5/TiO2催化剂的甲基吡啶氧化脱甲基性能

以锐钛矿TiO_2为载体,考察了CeO_2改性对Ag-CeO_2-V_2O_5/TiO_2催化3-甲基吡啶氧化脱甲基性能的影响,并优化了催化剂组成与制备条件.结果表明:Ce掺杂改性不仅能够与V物种作用形成Ce VO_4,而且促进V_2O_5分散,改善活性组分的氧化还原性能,从而提高3-甲基吡啶脱甲基转化率与选择性,改善Ag-V_2O_5/TiO_2催化性能.适宜的催化剂组成为V_2O_5负载量15%,Ce/V的摩尔比0.33,Ag质量分数1.0%.过高的焙烧温度将导致TiO_2载体向金红石型转变,Ag-CeO_2-V_2O_5/TiO_2适宜制备条件为450℃焙烧4 h.     

2-甲基吡啶的槽内式间接电氧化

在质子交换膜为隔膜的电解槽内, 以2-甲基吡啶为原料, 以Cr2O72-/Cr3+为媒质, 采用间接电氧化法研究了合成2-吡啶甲酸的反应条件. 实验结果表明, 硫酸浓度、硫酸铬浓度、 反应温度、2-甲基吡啶浓度和阳极电位对产率、转化率、 选择性和电流效率均有影响. 通过变化规律的研究, 找到了各个影响因素的最佳条件为: 硫酸浓度为6.0 mol/L, 反应温度为60 ℃, 硫酸铬浓度为0.15 mol/L, 2-甲基吡啶浓度为0.1 mol/L, 阳极电位为1.50 V.     

NHPI, CoSPc和TBAB催化的乙苯液-液非均相绿色氧化反应研究

以水为催化剂溶剂与原料乙苯组成液-液非均相体系,以NHPI结合CoSPc组成催化体系,在TBAB为相转移催化剂的作用下,对乙苯的氧化反应条件进行了研究.研究发现乙苯在该催化体系中的最佳氧化条件依次是:水油体积比为3∶1;n(TBAB)∶n(乙苯)=1∶40;n(NHPI)∶n(乙苯)=1∶10,n(NHPI)∶n(CoSPc)=24∶1,反应温度110℃,氧气压力0.75 MPa,搅拌速率350 rpm,反应时间0.5 h.在最佳反应条件下乙苯转化率为60.6%,苯乙酮的选择性为95.2%,1-苯乙醇的选择性为4.5%,产物总选择性达到了99.7%.在此基础上延长反应时间并不能提高乙苯的转化率,苯乙酮的选择性也会下降,研究发现NHPI的分解是乙苯转化率不随反应时间的延长而提高的原因,而苯乙酮的过度氧化为苯甲酸是产物选择性下降的原因.     

无碱条件下Au/ZnO选择性催化氧化1,3-丙二醇合成3-羟基丙酸甲酯

采用溶胶-沉积法合成了高选择性的Au/ZnO催化剂,用于1,3-丙二醇选择性氧化酯化为3-羟基丙酸甲酯的反应.研究了保护剂PVA用量、金溶胶合成温度、金负载量及催化剂循环利用对反应的影响,且优化了反应温度和反应压力,并对催化剂进行了XRD和TEM表征.结果表明,PVA∶Au(m/m)=1∶4、金溶胶合成温度25℃、金负载量1%的Au/ZnO对目标反应的催化活性最好,在100℃和Po2=2MPa的条件下1,3-丙二醇的转化率达82.8%,产物3-羟基丙酸甲酯的选择性达95.4%.Au纳米粒子的粒径影响催化性能,在Au平均粒径为2.8~6.1nm的范围内,产物选择性随Au纳米粒子的粒径的减小而增大,平均粒径在2.8~4.8nm的范围内时,催化剂具有较好的产物选择性(大于90%);Au/ZnO催化剂循环利用4次后催化性能(转化率和选择性)无明显下降;并推测了无碱条件下Au/ZnO选择性催化氧化1,3-丙二醇合成3-羟基丙酸甲酯的反应机制.     

4-氰基吡啶的合成

以4-甲基吡啶为原料,在固定床反应器中通过含氧化钒的催化剂发生气固相接触氨氧化反应制备雷米封中间体4-氰基吡啶,4-甲基吡啶的转化率为99％,4-氰基吡啶的选择性为88％,收率为87．12％。     

Magnetic Graphene Oxide Anchored Sulfonic Acid as a Novel Nanocatalyst for the Synthesis of N‐aryl‐2‐amino‐1,6‐naphthyridines

Magnetic graphene oxide functionalized with sulfonic acid (Fe₃O₄‐GO‐SO₃H) was used as a new recyclable nanocatalyst for one‐pot synthesis of N‐aryl‐2‐amino‐1,6‐naphthyridine derivatives under solvent free conditions. The catalyst could be easily recovered from the reaction mixture by an external magnet and reused without significant decrease in activity even after 4 runs. This nanocatalyst exhibited better activities to other commercially available sulfonic acid catalysts.     

无溶剂条件下反应控制相转移催化氯丙烯氧化制环氧氯丙烷

系统地研究了无溶剂条件下,H2O2为氧源,反应控制相转移催化剂[(C16H33(70%)+C18H37(30%))N(CH3)3]3[PW4O16]催化氯丙烯环氧化制环氧氯丙烷反应.结果表明,在氯丙烯/H2O2/催化剂(摩尔比)=400∶100∶1条件下,50～55℃反应3 h,环氧氯丙烷的收率为85～87%.在NaH2PO4存在下,催化剂循环使用5次,活性无明显降低,新鲜催化剂和回收催化剂的31P MAS NMR谱分析结果表明NaH2PO4对催化剂结构和组成具有稳定作用.     

果糖在酸性离子液体中脱水制备5-羟甲基糠醛

制备了多种离子液体,并将其作为催化剂和溶剂催化果糖脱水制备5-羟甲基糠醛（HMF）。 制备的酸性离子液体包括磺酸基功能化酸性离子液体、咪唑类酸性离子液体和吡啶类酸性离子液体。 利用核磁共振仪和红外光谱仪对离子液体的结构进行表征。 利用紫外可见光分光光度计结合Hammett指示剂计算Hammett酸度函数,比较了酸强度的大小对反应的影响。 结果表明,离子液体的酸强度对反应有较大影响,在无其它催化剂和溶剂的情况下,离子液体具有较高的催化活性,通过使用1-丁基-3-甲基咪唑氯盐(BmimCl)作为催化剂,当反应温度为120 ℃,反应进行到4 h时,HMF收率可以达到74.97%。     

Sulfonic acid supported on magnetic nanoparticle as an eco‐friendly,durable and robust catalyst for the synthesis of β‐amino carbonyl compounds through solvent free Mannich reaction

A simple, efficient and environmentally benign solid acid catalyst was prepared by anchoring a propyl sulfonic acid on the surface of silica‐coated magnetic nanoparticles by low cost precursors. The catalyst has been then engaged in the efficient β‐amino carbonyl compounds production via three component Mannich reaction under solvent free reaction condition at room temperature. After the completing the reaction, the catalyst was readily separated by external magnet and reused for 10 successive rounds of reaction, without any significant loss in catalytic efficiency. The solid acidic system presented reusable strategy for the efficient synthesis of β‐amino carbonyl compounds, simplicity in operation, and green aspects by avoiding toxic conventional catalysts under solvent‐free condition.     

溶胶-凝胶法制备负载磷钼杂多酸铵催化苯硝化反应

以正硅酸乙酯为硅源,利用溶胶-凝胶法制备负载磷钼杂多酸铵催化剂（AMPA/SiO2）,采用X射线衍射和红外光谱测试技术对催化剂进行了表征,并初步评价了催化剂苯硝化反应催化性能。结果表明,溶胶-凝胶法制备的AMPA/SiO2保持了磷钼酸铵（AMPA）杂多酸盐的Keggin结构。AMPA以及AMPA/SiO2催化剂均表现出较强的苯硝化反应催化活性和100 ％的一硝基苯选择性,苯最高转化率为96 ％。反应后负载催化剂活性组分有所损失,但催化剂整体物相和结构没有发生明显变化。     

Preparation and characterization of Cu supported on 2-(1H-benzo[d]imidazol-2-yl)aniline-functionalized Fe3O4 nanoparticles as a novel magnetic catalyst for Ullmann and Suzuki cross-coupling reactions

Copper supported on 2-(1H-benzo[d]imidazol-2-yl)aniline (BIA)-functionalized Fe₃O₄ nanoparticles (Cu-BIA-Si-Fe₃O₄) as a novel magnetic catalyst was designed and used for the synthesis of new products via Ullmann and Suzuki cross-coupling reactions. The Ullmann reaction was performed by mixing arylboronic acid with aniline derivatives in dimethylsulfoxide solvent. Also, diaryls were synthesized via Suzuki C–C reactions between aryl halides and phenylboronic acid in the same solvent. The prepared materials and catalyst were characterized with various analytical techniques. The Cu-BIA-Si-Fe₃O₄ catalyst demonstrated catalytic efficiency with good to excellent yields for both types of reactions in comparison with commercial palladium catalysts. Also, the catalyst could be recovered by a simple filtration and retained its activity even after several cycles.     

Carbon deposition on meso-porous Al2O3 supported Ni catalysts in methane reforming with CO2

Summary 4-(Trialkylammonio)propansultans (TAAPSs), synthesized by the addition reaction of 1,3-propane sultone (PS) and trialkylamines (TAAs), were developed as new phase transfer catalysts for synthesizing dialkoxymethane. The reaction between alcohol and dibromomethane in a highly alkaline solution of KOH/organic solvent two-phase medium were carried out under phase-transfer catalysis (PTC) using TAAPSs as the catalyst. High conversion of dibromomethane and high selectivity of the product were obtained using TAAPSs as the catalyst.</o:p>     

An expeditious and greener one-pot synthesis of 4H-chromenes catalyzed by Ba(OTf)2 in PEG-water

Abstract

An expeditious synthesis of 4H-chromenes has been achieved by three-component one-pot condensation of 1,3-diketone, aldehyde, and malononitrile using Ba(OTf)₂ as catalyst in PEG-water at room temperature. Results from various reaction media and different metal triflates as catalysts show that choice of proper catalyst and the solvent system play a key role in the synthesis of 4H-chromene-3-carbonitrile derivatives. The catalyst can be recovered and reused at least five times without loss of activity. The application of an eco-friendly, noncorrosive, and reusable catalytic system with high isolated yield of the products makes this method advantageous.     

固体酸催化二氟二苯甲酮和苯胺缩合合成N-(双(4-氟苯基)亚甲基)苯胺

以固体酸为催化剂,4,4’-二氟二苯甲酮与苯胺脱水缩合,合成了N-(双(4-氟苯基)亚甲基)苯胺.比较了不同固体酸催化剂H型ZSM-5、Na型ZSM-5、介孔分子筛MCM-41(Al)及强酸型离子交换树脂Amberlyst 15的催化效果.使用比表面、NH3-TPD对催化剂进行了表征,并与催化效果关联.考察了催化剂用量、原料摩尔比、浓度及溶剂等反应条件对产物收率的影响.产物通过熔点、核磁共振谱进行了表征.结果表明,HZSM-5固体酸催化剂具有优异的催化作用.在优化条件下,以对二甲苯为反应溶剂和脱水剂,4,4’-二氟二苯甲酮0.1 mol,苯胺0.2 mol,催化剂用量2.0 g,反应24 h,产物收率达91%.此外,催化剂易于分离,能够重复使用多次.     

Kinetic study of the phase-transfer catalytic epoxidation of 1,4-bis(allyloxy)butane

The epoxidation of 1,4-bis(allyloxy)butane (DiBan) with hydrogen peroxide as an oxidant in the presence of o-phosphoric acid and sodium tungstate as an epoxidation catalyst was carried out in an organic solvent/aqueous solution two-phase medium. A few different phase-transfer catalysts were used in the process. The effect of the stirring speed, nature of solvent, the type of PT catalyst and molar ratio of H(2)O(2):DiBan, DiBan:Na(2)WO(4):H(3)PO(4) on the DiBan conversion as the function of time was studied. Based on the experimental results, a pseudo-first-order expression for the reaction rate was applied and most efficient conditions epoxidation were developed.