丙酮缩合法合成甲基异丁基酮的研究进展

丙酮是廉价易得的化工原料,是异丙苯氧化裂解法生产苯酚时的副产物,目前国内产能过剩。甲基异丁基酮是一种有着广泛用途的化工中间体。因此,将丙酮通过缩合加氢生产制备甲基异丁基酮,能够消耗产能过剩的化合物,生产市场需求旺盛的产品,是非常重要的有机化学反应,具有巨大的工业应用前景。本文对丙酮缩合法合成甲基异丁基酮反应的研究进展进行整理与系统性地阐述,供国内相关领域技术人员参考。     

异丙醇还原法制备甲基异丁基酮的研究

目前,国内丙酮产能过剩.将丙酮转化为市场需求较大的高附加值产品,具有实际的应用价值.甲基异丁基酮(MIBK)是重要的工业中间体,有广泛的用途和广阔的市场.因此,利用丙酮为原料合成甲基异丁基酮,有巨大的工业应用前景.报道了以丙酮为原料,通过缩合、还原等步骤合成MIBK的简便方法.与传统方法不同之处在于,该方法中还原丙酮缩合产物异丙叉丙酮(MO)时,并不使用较危险的氢气,而使用异丙醇作还原剂.还原剂氧化后产生的副产物丙酮可重新回收利用.通过反应条件的优化,可将MO转化率提高到95.8%,MIBK选择性达98.8%.反应还可以通过一锅两步法进行.     

丙酮一步法合成甲基异丁基酮催化剂研究

用浸渍法制备了丙酮一步法合成甲基异丁基酮负载型催化剂，考察了载体的预处理温度、添加镧助剂对催化剂性能的影响；用BET法测定了催化剂的表面积；采用H2-O2滴定法测定Pd的分散度．结果发现，用经过1．023K焙烧过的Al2O3为载体的催化剂具有较好的催化性能，添加镧助剂后催化剂的分散度、活性有较大的提高．     

以镁铝水滑石为前驱体制备复合氧化物催化丙酮气相缩合反应

采用共沉淀-恒温晶化法制备了系列镁铝水滑石(Mg-Al-LDH)样品,对镁铝水滑石在500 ℃焙烧得到镁铝复合氧化物(Mg-Al-LDO),采用IR、XRD、CO₂-TPD、SEM及N₂吸附-脱附等方法对Mg-Al-LDH和Mg-Al-LDO进行了表征。在温度250 ℃、液时空速1 h^-1条件下,采用固定床对镁铝复合氧化物催化剂对丙酮缩合反应的性能进行微反活性评价。研究结果表明,晶化时间与镁铝复合氧化物的弱碱性位和强碱性位的密度相关。丙酮缩聚反应的主要产物为异佛尔酮(IP)和异丙叉丙酮(MO),以及少量的异丙烯基丙酮、双丙酮醇,均三甲苯等。丙酮缩聚制备异佛尔酮的反应需要催化剂表面弱碱性位(S_w)与强碱性位(S_s)的协同作用,S_w与S_s需要匹配。晶化12 h得到的镁铝复合氧化物催化剂(LDO-12)的S_w/S_s=1.3,异佛尔酮(IP)选择性为65.3%,单程有效收率(IP+MO)为14.8%。     

Ni,Pd／Al2O3对丙酮加氢一步合成甲基异丁基酮性能比较

研究了Ａｌ２Ｏ３负载Ｎｉ、Ｐｄ催化剂上丙酮加氢一步合成甲基异丁基酮的反应活性。考察了不同Ｎｉ含量和不同Ｐｄ含量对活性的影响。结果表明，在载体Ａｌ２Ｏ３中加入不同含量的ＳｉＯ２后，会改善载体的性能，Ｎｉ／Ａｌ２Ｏ３催化剂中添加稀土元素Ｌａ或Ｃｅ后可改善催化剂的稳定性。     

(R)-甘油醛缩丙酮的合成及Wittig反应选择性

D-(R)-甘油醛缩丙酮是近年来研究的很多的一种用来合成一些手性药物和具有光学活性的天然产物的重要前体.用Lew is酸无水ZnC l2作为催化脱水剂,D-甘露醇与丙酮缩合反应合成二异亚丙基缩合物,然后用NaIO4氧化断键制备D-(R)-甘油醛缩丙酮,该方法具有产率高、价廉、环境友好等优点.主要研究了(R)-甘油醛缩丙酮W ittig反应的立体选择性.     

二羟基丙酮磷酸酯的合成

本文报道由3-氯-1,2-丙二醇(1)经七步反应,合成二羟基丙酮磷酸酯缩乙酮(7)的方法,总收率43%。在温和条件下,7可以水解为游离的二羟基丙酮磷酸酯(8)。     

水对Ni/MgAlO催化丙酮加氢的影响

研究了H2O对Ni/MgAlO催化剂上丙酮加氢为异丙醇的催化反应的影响。结果发现,在丙酮中添加少量H2O可提高丙酮转化率,但超过5%的H2O量则会显著降低催化剂活性。吸附量热结果表明,催化剂表面吸附少量H2O会明显降低异丙醇的吸附热,但对丙酮吸附热的影响较小,这也许是反应体系中少量的H2O能促进丙酮加氢活性的原因之一。当催化剂表面吸附较多H2O后,丙酮、异丙醇和H2的吸附热都降低了,因此反而抑制了丙酮的加氢反应。此外,红外光谱结果表明,预吸附水抑制了催化剂表面异丙醇脱氢生成丙酮,并抑制吸附的丙酮在表面生成烯醇盐或异丙叉丙酮等物种,这也许是少量水能促进丙酮加氢生成异丙醇的另一个重要原因。     

水对Ni/MgAlO催化丙酮加氢的影响

研究了H2O对Ni/MgAlO催化剂上丙酮加氢为异丙醇的催化反应的影响。结果发现,在丙酮中添加少量H2O可提高丙酮转化率,但超过5%的H2O量则会显著降低催化剂活性。吸附量热结果表明,催化剂表面吸附少量H2O会明显降低异丙醇的吸附热,但对丙酮吸附热的影响较小,这也许是反应体系中少量的H2O能促进丙酮加氢活性的原因之一。当催化剂表面吸附较多H2O后,丙酮、异丙醇和H2的吸附热都降低了,因此反而抑制了丙酮的加氢反应。此外,红外光谱结果表明,预吸附水抑制了催化剂表面异丙醇脱氢生成丙酮,并抑制吸附的丙酮在表面生成烯醇盐或异丙叉丙酮等物种,这也许是少量水能促进丙酮加氢生成异丙醇的另一个重要原因。     

含糖基水溶性紫外吸收剂的合成与表征

以三聚氯氰(TCT)、2,4-二羟基二苯甲酮(UV-0)、双丙酮葡萄糖为原料,经三步反应合成一种具有反应性基团的水溶性紫外吸收剂3-(2-(2-羟基苯基苯甲酮-4-氧基)-4-氯-1,3,5-三嗪-6-氧基)-1,2-异丙叉-α-D-葡萄糖(UV-DTM),产物的结构经IR、NMR和MS表征。探讨了每一步反应的条件对反应产率的影响。合成3-(4,6-二氯-1,3,5-三嗪-2-氧基)-1,2,5,6-双异丙叉-α-D-葡萄糖(DTDT)的优化反应条件为:n(三聚氯氰)∶n(双丙酮葡萄糖)∶n(Na OH)=0.9∶1∶1.7,在丙酮和水的混合体系中0℃下反应8h,产率73%。合成3-(2-(2-羟基苯基苯甲酮-4-氧基)-4-氯-1,3,5-三嗪-6-氧基)-1,2,5,6双异丙叉-α-D-葡萄糖(UV-DT)的优化条件为:n(DTDT)∶n(UV-0)∶n(Na OH)=1∶1.1∶1,在丙酮和水的混合体系中30℃下反应2h,产率74%。合成UV-DTM的优化条件为:每1mmol UV-DT与0.5m L盐酸(36%)在THF体系中25℃下反应5h,产率74%。UV-DTM的紫外吸收性能在240~400 nm内表现良好,水溶性得到大幅改善。     

The Role of Potassium Cation in the Favorskii Ethynylation of Acetone: Effekt of Dibenzo-18-crown-6

Macrocyclic polyether dibenzo-18-crown-6 possessing a specific affinity for potassium cation inhibits ethynylation of acetone with acetylene in the presence of KOH according to Favorskii. The inhibition becomes stronger in the presence of the complex dibenzo-18-crown-6 ? KOH ? MeOH as catalyst (both in excess acetone and in DMSO). The effect does not originate from deactivation of acetone, for its aldol-like condensation is accelerated in the presence of both dibenzo-18-crown-6 and its complex (the selectivity of ethynylation sharply falls down). Thus, apart from the high basicity of the medium, activation of acetylene due to complex formation with potassium cation plays an important role in the Favorskii ethynylation of ketones.     

A DFT study of IRMOF-3 catalysed Knoevenagel condensation

It has been recently reported that IRMOF-3 [Gascon et al., J. Catal, 2009, 261, 75] may behave as a basic catalyst, active in the Knoevenagel condensation. In particular, it has been shown that the basicity of aniline-like amino moieties is enhanced, along with the catalytic activity, when incorporated into MOF structures. The computational study here was aimed at finding possible atomistic explanations of the increased basicity and catalytic activity of the IRMOF-3 embedded aniline groups, experimentally claimed. It was, moreover, aimed at guessing a reaction mechanism for the IRMOF-3 catalysed Knoevenagel condensation of benzaldehyde and ethyl-cyanoacetate. Within the DFT framework we have studied structure and basicity properties of IRMOF-3 and we have analysed the energetics of the catalytic cycle as well as of possible deactivation paths, including it. The increased basicity of IRMOF-3 over other amminic catalysts has been explained via the formation of protonated conjugate derivatives, involving hydrogen-bonds and originating quasi-planar 6-term rings. Several plausible reaction steps have been moreover taken into account and a mechanism for the Knoevenagel condensation, including catalyst deactivation, has been proposed for aniline molecules and embedded aniline moieties. This allowed us to suggest that the increased IRMOF-3 activity, as a basic catalyst, should be mostly related to its water adsorption ability, preserving the properties of the catalytically active amino moieties.     

在阴离子交换树脂催化剂上合成二丙酮醇的动力学研究

动力学研究表明,在碱性树脂催化剂上丙酮缩合制二丙酮醇是一个1-1级可逆反应,本文对此多相催化的反应机理进行了探讨。     

沸石的碱性催化:乙醇双分子缩合反应

本文首次发现在碱性沸石上乙醇参数发生以正丁醇为主产物的双分子缩合反应。在所研究的催化剂中, 含铷的LiX沸石表现出最高的反应选择性。研究表明, 这一碱化反应的活性与催化剂的酸碱性质密切相关。催化剂的碱性对反应起决定作用,但催化剂的碱性太强则不利于反应。     

Metal- and Solvent-Free Transesterification and Aldol Condensation Reactions by a Homogenous Recyclable Basic Ionic Liquid Based on the 1,3,5-Triazine Framework

A new recyclable basic ionic liquid was introduced as an efficient catalyst for aldol condensation and transesterification reactions under environmentally friendly conditions. The catalyst was prepared based on methyl imidazolium moieties bearing hydroxide counter anions via the Hofmann elimination on a 1,3,5-triazine framework. The ionic liquid with two functionalities including anion stabilizer and high basicity, was used as an efficient catalyst for aldol condensation as well as transesterification reaction of a variety of alkyl benzoates. All reactions were performed in the absence of any external reagent, co-catalyst, or solvent, in line with environmental protection. The kinetics isotope effect (KIE) was conducted for the transesterification reaction to elucidate the mechanism and rate determining step (RDS). It worth noted that, the homogeneous catalyst could be recycled from the reaction mixture and reused for several consecutive runs with insignificant drop of basicity and conversion.     

富氮多孔有机聚合物催化制备α⁃氰基肉桂酸乙酯

α-氰基肉桂酸乙酯作为含多种官能团的缺电子烯烃, 是一种极具应用价值的有机合成反应底物, 主要通过催化Knoevenagel缩合反应获得. 本文以多聚甲醛和三聚氰胺为前驱体, 采用溶剂热法制备富氮多孔有机聚合物mPMF, 经K₂CO₃处理得到K₂CO₃-mPMF-X(X=1, 10, 50). 考察了mPMF在苯甲醛和氰乙酸乙酯Knoevenagel缩合反应中的催化性能, 通过mPMF与K₂CO₃-mPMF-X催化活性的比较, 探讨了碱性强弱对Knoevenagel缩合反应的影响, 并对催化反应机理进行了探索. 结果表明, 催化剂中丰富的氮物种为反应提供了碱性环境和大量的碱性活性位点, 催化剂碱性强弱的控制是催化合成α-氰基肉桂酸乙酯的关键因素. mPMF在甲醇溶剂中于60 ℃反应3 h后, 苯甲醛转化率为97%, 目标产物选择性在99.9%以上.     

Supported hydrotalcites as highly active solid base catalysts

Mg-Al hydrotalcite platelets with a lateral size of 20 nm were deposited on carbon nanofibers and the resulting supported catalyst exhibited a specific activity in the condensation of acetone four times that of unsupported hydrotalcites due to the higher number of active edge sites.     

载Ni双功能碱性沸石催化剂的研究

采用分步浸渍法制备了负载Ni和KOH的NaX沸石催化剂 ,用XRD、TPR、CO2 TPD和XPS等手段对样品的结构、表面碱性、金属组分的可还原性、表面Ni物种的形态等进行了表征 ,对金属组分和碱性组分间的相互作用进行了研究 ,并揭示了这种作用的本质.同时结合丙酮一步法合成甲基异丁基酮的反应 ,探讨了反应性与样品碱性、金属性的关系 ,阐明了该反应中双功能催化剂上金属组分与碱性组分必须匹配合宜的原因     

共沉淀法制备的镁铝氧化物催化剂上丙酮气相缩合反应

采用共沉淀法, 以氨水为沉淀剂制备了一系列具有不同Mg/Al摩尔比的镁铝氧化物催化剂, 考察了它们在丙酮气相缩合反应中的催化性能, 并通过XRD, XPS, ICP, TG-DTA和TPD等手段对催化剂的结构和性质进行了表征. 实验结果表明, 以反滴沉淀方式制备的Mg1.0AlO催化剂具有较高的反应活性和稳定性, 在反应温度为573 K条件下, 反应85 h后丙酮的转化率仍可以达到65%. 镁铝氧化物表面存在一定量强度和密度相互匹配的弱碱和强碱中心对提高催化剂的活性和稳定性有利.     

A simple modification creates a great difference: new solid-base catalyst using methylated N-substituted SBA-15

A simple modification, methylation of the nitrogen-substituted mesoporous silica SBA-15, enhances the basicity of a solid-base catalyst. The methyl group donates an electron to the nitrogen atom in the silica framework. This catalyst accelerates Knoevenagel condensation using benzaldehyde and diethyl malonate, which conventional solid-base catalysts reported to date cannot do. This report demonstrates a possible new type of base catalyst using nitrogen-substituted mesoporous silica materials.