硒催化1,4-丁二胺羰基化合成1,3-二氮杂环庚烷-2-酮的研究

以廉价易得的非金属硒作催化剂,一氧化碳作羰基化试剂,氧气作氧化剂,在获得的优化条件下,经"一锅法"的硒催化1,4-丁二胺的分子内氧化羰基化反应能以71%收率制得目标产物1,3-二氮杂环庚烷-2-酮。该方法具有路线简短、原子经济性高、成本低、环境相对友好等优点。     

硒催化2-氨基苄醇氧化羰基化合成1,4-二氢-2H-3,1-苯并噁嗪-2-酮

1,4-二氢-2H-3,1-苯并噁嗪-2-酮作为一种重要的母体骨架广泛存在于生物活性化合物中。此外,在有机合成中它可作为经受热脱羧生成氮杂-邻二亚甲基苯的有效工具。文献报道的合成1,4-二氢-2H-3,1-苯并噁嗪-2-酮的方法有：2-氨基苄醇与光气或其替代物反应,钯或硫催化的2-氨基苄醇与 CO的羰基化反应,钯或硒催化的2-硝基苄醇与 CO的羰基化反应,钯催化的2-叠氮基苄醇直接羰基化反应或2-叠氮基苄醇的氮杂-维悌希(aza-Wittig)/杂累积多烯调节的环合反应,苯并呋喃酮的胺解-霍夫曼重排反应,硼氢化锂还原1,2-二氢-3,1-苯并噁嗪-2,4-二酮,以及2-羟甲基苯基氨基甲酸酯的分子内亲核取代反应。上述合成方法存在原料毒性高或成本高且来源不便、原子经济性低、有腐蚀性废物或 CO2排放、CO利用率低、催化剂昂贵且难以循环使用、反应步骤较多等缺陷,因此发展绿色、高效、经济的合成新途径具有重要意义。本文采用廉价易得的非金属硒作催化剂,用 CO作羰基化试剂, O2作氧化剂,通过硒催化2-氨基苄醇的氧化羰基化反应直接合成了目标产物1,4-二氢-2H-3,1-苯并噁嗪-2-酮。通过考察反应时间、反应温度、催化剂硒的用量、助催化剂种类及用量、CO和 O2的比例及溶剂种类等影响因素,得到了优化的反应条件,目标产物收率最高可达87%。实验证实,该 Se/CO催化体系具有相转移催化功能。反应前硒以粉末形式存在于反应体系中,为多相体系;反应开始后,硒粉参与羰基化反应形成可溶活性化合物,从而成为均相体系;反应完成后硒粉经氧化可重新从反应介质中沉淀析出,又变为多相体系。因此,该体系既实现了高效的均相催化反应,又便于催化剂分离回收,且回收的硒可重复使用,其催化活性基本保持不变。结合相关文献,我们提出了该反应的机理：在助催化剂三乙胺存在下,硒首先与 CO反应原位生成羰基硒,然后羰基硒先后接受2-氨基苄醇中氨基和羟基的亲核进攻生成目标产物,同时释放出硒化氢,硒化氢再被 O2氧化为硒,从而进入下一轮催化循环反应。总之,我们成功开发出一条绿色、高效、经济的1,4-二氢-2H-3,1-苯并噁嗪-2-酮合成新途径。用廉价易得且能循环使用的硒替代贵金属钯作催化剂,用 CO替代剧毒光气或其衍生物作羰基化试剂, O2作氧化剂,硒催化的2-氨基苄醇氧化羰基化反应可顺利进行,以87%的良好收率得到目标产物,具有成本低、原子经济性高、CO利用率高、步骤简短、无腐蚀性废物或温室气体 CO2排放、无光气使用及环境相对友好等优点。     

硒催化2-氨基苄醇氧化羰基化合成1,4-二氢-2H-3,1-苯并噁嗪-2-酮（英文）

1,4-二氢-2H-3,1-苯并噁嗪-2-酮作为一种重要的母体骨架广泛存在于生物活性化合物中.此外,在有机合成中它可作为经受热脱羧生成氮杂-邻二亚甲基苯的有效工具.文献报道的合成1,4-二氢-2H-3,1-苯并噁嗪-2-酮的方法有:2-氨基苄醇与光气或其替代物反应,钯或硫催化的2-氨基苄醇与CO的羰基化反应,钯或硒催化的2-硝基苄醇与CO的羰基化反应,钯催化的2-叠氮基苄醇直接羰基化反应或2-叠氮基苄醇的氮杂-维悌希(aza-Wittig)/杂累积多烯调节的环合反应,苯并呋喃酮的胺解-霍夫曼重排反应,硼氢化锂还原1,2-二氢-3,1-苯并噁嗪-2,4-二酮,以及2-羟甲基苯基氨基甲酸酯的分子内亲核取代反应.上述合成方法存在原料毒性高或成本高且来源不便、原子经济性低、有腐蚀性废物或CO_2排放、CO利用率低、催化剂昂贵且难以循环使用、反应步骤较多等缺陷,因此发展绿色、高效、经济的合成新途径具有重要意义.本文采用廉价易得的非金属硒作催化剂,用CO作羰基化试剂,O_2作氧化剂,通过硒催化2-氨基苄醇的氧化羰基化反应直接合成了目标产物1,4-二氢-2H-3,1-苯并噁嗪-2-酮.通过考察反应时间、反应温度、催化剂硒的用量、助催化剂种类及用量、CO和O_2的比例及溶剂种类等影响因素,得到了优化的反应条件,目标产物收率最高可达87%.实验证实,该Se/CO催化体系具有相转移催化功能.反应前硒以粉末形式存在于反应体系中,为多相体系;反应开始后,硒粉参与羰基化反应形成可溶活性化合物,从而成为均相体系;反应完成后硒粉经氧化可重新从反应介质中沉淀析出,又变为多相体系.因此,该体系既实现了高效的均相催化反应,又便于催化剂分离回收,且回收的硒可重复使用,其催化活性基本保持不变.结合相关文献,我们提出了该反应的机理:在助催化剂三乙胺存在下,硒首先与CO反应原位生成羰基硒,然后羰基硒先后接受2-氨基苄醇中氨基和羟基的亲核进攻生成目标产物,同时释放出硒化氢,硒化氢再被O_2氧化为硒,从而进入下一轮催化循环反应.总之,我们成功开发出一条绿色、高效、经济的1,4-二氢-2H-3,1-苯并噁嗪-2-酮合成新途径.用廉价易得且能循环使用的硒替代贵金属钯作催化剂,用CO替代剧毒光气或其衍生物作羰基化试剂,O_2作氧化剂,硒催化的2-氨基苄醇氧化羰基化反应可顺利进行,以87%的良好收率得到目标产物,具有成本低、原子经济性高、CO利用率高、步骤简短、无腐蚀性废物或温室气体CO_2排放、无光气使用及环境相对友好等优点.     

硒催化的邻硝基苯胺类化合物的羰基化反应

用硒作催化剂，三乙胺为助催化剂，CO为羰基化试剂，通过氧化还原羰基化的方法，将邻硝基苯胺类化合物在分子内羰基化成环，反应生成相应的一系列环脲类物质，此催化合成方法的反应选择性近秋100％，收率较高，操作简单，并提出了可能的反应机理。     

硒催化羰基化合成苯氨基甲酸酯和二苯甲烷二氨基甲酸酯

首先以廉价易得的非金属硒作催化剂,CO替代剧毒光气作羰基化试剂,O2作氧化剂,通过硒催化苯胺与醇"一锅煮"的氧化羰基化反应制得苯氨基甲酸酯;然后在HCl/ZnCl_2催化下再与甲醛缩合制得二苯甲烷二氨基甲酸酯.两反应的目标产物收率从中等到良好,底物普遍适用性广.CO利用率及原子经济性高,且避免了剧毒光气的使用.催化剂硒具有相转移催化作用,便于回收且能循环使用.合成方法清洁、经济、高效.提出了可能的反应机理.     

2-硒代咪唑类化合物催化CO与胺的羰基化反应

首次研究了2-硒代咪唑类化合物催化的一氧化碳对胺的羰基化生成对称脲或噁唑啉-2-酮的反应,目标产物收率中等到良好.与传统的单质硒催化的羰基化反应相比,新催化体系有效避免了有恶臭气味的含硒化合物的产生.     

硒催化硝基苯的还原羰基化生成苯氨基甲酸酯

详细考察了醇介质中硒催化的硝基苯还原羰基化生成苯氨基甲酸酯的反应,获得了一系列苯氨基甲酸酯产物。结果表明,硒粉催化活性高,反应产率和选择性良好,反应工艺简单。文中对反应提出了可能的机理。     

一氧化碳参与不饱和烃类化合物羰基化反应的研究进展

不饱和烃类化合物的羰基化反应是指在过渡金属催化剂存在条件下, 将一氧化碳(CO)分子以羰基的形式插入到烯烃(或者炔烃)与不同的亲核试剂中, 合成更高附加值化学品的转化过程. 本文综合评述了羰基化反应合成高附加值化学品的重要性, 介绍了几种不同类型的羰基化反应(氢甲酰化反应、 氢酯化反应、 氢酰胺化反应和氢羧基化反应)在发展新型催化剂体系及高效合成目标产物方面的研究进展, 并对羰基化反应存在的问题及未来发展方向和趋势进行了展望.     

硒催化法合成2-吡啶脲的研究

 采用硒催化的一氧化碳还原羰基化法,由硝基苯衍生物与2－氨基吡啶进行反应,得到的不是比例相当的三种脲类物质混合物,而主要得到非对称的吡啶脲．进一步发展了硒／一氧化碳催化体系对硝基化合物的还原羰基化法,可望用来合成一系列含取代基的苯基吡啶基脲类物质;该合成方法工艺简单,操作易行．对部分产物进行了红外光谱、核磁共振谱、高压液相色谱及元素分析等鉴定．     

丝光沸石催化二甲醚羰基化研究进展

二甲醚羰基化反应是在二甲醚分子中定向插入一氧化碳的重要增碳反应,在工业生产中具有重要意义.近年来,研究发现廉价的丝光沸石可催化二甲醚羰基化反应,且具有较高的反应活性和十分优异的羰基化产物选择性,因此,得到了广泛的研究.本文对丝光沸石催化二甲醚羰基化的研究进行综述,介绍了羰基化反应的机理,并总结丝光沸石内部酸性位点调控的...     

钯催化芳基偶氮的氧化羰基化反应

采用TBHP作为氧化剂,发展了钯催化芳基偶氮化合物N＝N双键断裂的氧化羰基化反应.芳基偶氮的羰基化反应在Pd(OAc)2(5％),MeO-BIPHEP (5％),芳基偶氮(0.2 mmol),TBHP(2 equiv),H2O(1 equiv),DCE(1 mL),CO (3.0 MPa)的条件下110℃反应12h后,经柱层析纯化分离得到31％-91％的芳基脲.初步的机理研究表明,芳基偶氮化合物的N＝N双键断裂原位产生芳基胺,再进一步氧化羰基化生成芳基脲.     

Supramolecular binding of amines with functional magnesium tetraphenylporphyrin for CO2 capture

In this work,magnesium tetraphenylporphyrin (MgTPP) was used as a new supramolecular amine-fixing agent. Once introduced, CO2 easily competes with MgTPP for amines, leading to the release of MgTPP. The processes can be explained by the fact that the association constant (Kassoc) values of MgTPP with amines were in the range of 0.6 (ethanolamine) to 3.9 (ethylenediamine), which are lower than the Kassoc values of CO2 with these amines. MgTPP interacted with aniline, ethanolamine, pyrrolidine, or ethylenediamine to form 1:1 adducts. Ethylenediamine presents a stronger Kassoc value for MgTPP, so it was considered an optimal agent for CO2 capture.     

Pd(OAc)2-catalyzed carbonylation of amines

A phosphine-free catalytic system [Pd(OAc)2-Cu(OAc)2-air] induced a substrate-specific carbonylation of amines in boiling toluene under CO gas (1 atm). Symmetrical N,N'-dialkylureas were obtained by the carbonylation of primary amines. N,N,N'-Trialkylureas were selectively formed by addition of a secondary amine to the above reaction vessel. Secondary amines did not give tetraalkylureas. However, dialkylamines with a phenyl group on their alkyl chains, such as N-monoalkylated benzylic amine or phenethylamine derivatives, underwent a direct aromatic carbonylation to afford five- or six-membered benzolactams. In the carbonylation, the chelation effect or steric repulsion between Pd(II) and the meta-substituent in the ortho-palladation and the ring sizes of cyclopalladation products that were formed prior to carbonylation were found to generate good site selectivity and increase the reaction rate. In contrast, carbonylation of omega-arylalkylamines with a hydroxyl group gave neither ureas nor benzolactams but instead produced 1,3-oxazolidinones smoothly. Hydrochlorides of amines also underwent carbonylation to afford the corresponding amides under the conditions used. This procedure made it possible to prepare ureas of amino acid esters and N-alkylcarbamates in practical yields.     

Effect of amines on vinyl polymerization initiated by chromous acetate–alkyl halide systems

The radical polymerization of vinyl monomers initiated by Cr²⁺–RX in the presence of various amines was studied in DMF at 30°C. Polyamines able to form the chelate complex with Cr²⁺ accelerated the rate of polymerization of styrene in the following order: ethanolamine > triethylenetetramine > diethylenetriamine > ethylenediamine. However, aliphatic monoamine, hexamethylenediamine, and aromatic diamine did not have any effect on the polymerization. These results suggest that the effect of multidentate ligands may be associated with chelating effects which affect the electron transfer ability of the metal complex. An apparent activation energy of 8.2 kcal/mole for the polymerization of styrene was obtained in the presence of ethanolamine. With the Cr²⁺–CHCl₃ system, on addition of ethanolamine, the polymerization of methyl methacrylate was accelerated, and acrylonitrile and vinyl chloride, could be polymerized.     

Catalytic oxidative carbonylation of primary and secondary diamines to cyclic ureas. Optimization and substituent studies

W(CO)(6)-catalyzed oxidative carbonylation of 1,3-propanediamine to the corresponding urea has been examined under a variety of conditions. Following optimization, the Thorpe-Ingold effect on ring closure was studied using 2,2-dialkyl-1,3-propanediamines. For the 2,2-dimethyl- and 2,2-dibutyl-1,3-propanediamines, the yields were increased significantly as compared to that of the unsubstituted case. The eight-membered cyclic urea 5-butyl-5-ethyl-1,3-diazepan-2-one (5f) was formed in 38% yield, while only trace amounts of the cyclic urea were produced from the parent 1,5-pentanediamine. In a study of secondary diamines, yields from the carbonylation of N,N'-dialkyl-2,2-dimethyl-1,3-propanediamines were lower than those obtained from the primary diamines. The main byproducts from secondary diamines were tetrahydropyrimidine derivatives formed from a competitive reaction of the substrate with the oxidant and base.     

W(CO)6-catalyzed oxidative carbonylation of primary amines to N,N'-disubstituted ureas in single or biphasic solvent systems. Optimization and functional group compatibility studies

Primary amines undergo carbonylation to N,N'-disubstituted ureas using W(CO)6 as the catalyst, I2 as the oxidant, and CO as the carbonyl source. Preparation of various N,N'-disubstituted ureas from aliphatic primary amines, RNH2 (R = n-Pr, n-Bu, i-Pr, sec-Bu, or t-Bu), was achieved in good to excellent yields. Studies of functional group compatibility using a series of substituted benzylamines demonstrated broad tolerance of functionality during the carbonylation reaction. Preparation of various N,N'-disubstituted ureas from substituted benzylamines, R-C6H4CH2NH2 (R = H, p-OCH3, p-CO2H, p-CO2Et, p-CH2OH, p-SCH3, p-vinyl, p-Cl, p-Br, m-I, p-NH2, p-NO2, or p-CN), was achieved in good yields. For many substituted benzylamines, yields of ureas were higher when a two-phase CH2Cl2/H2O solvent system was used.     

Visible-Light-Induced Palladium-Catalyzed Dehydrogenative Carbonylation of Amines to Oxalamides

The palladium-catalyzed oxidative carbonylation of amines toward the synthesis of oxalamides has been established around 30 years ago and it usually needs the presence of (over)stoichiometric amounts of oxidant. In this work, the first transformation of this type in which the oxidant was replaced by visible light is described. The new approach uses a simple robust Pd complex, which can even be partially recycled. A mechanistic reason is provided and supported by control experiments and EPR studies, showing that Pd^I was formed and Pd⁰ was the active species. Both nitrogen- and the intermediate acyl radical can be detected. Moreover, the formation of hydrogen was confirmed by gas GC.     

Oxidations of N-(3-indoleethyl) cyclic aliphatic amines by horseradish peroxidase: the indole ring binds to the enzyme and mediates electron-transfer amine oxidation

Although oxidations of aromatic amines by horseradish peroxidase (HRP) are well-known, typical aliphatic amines are not substrates of HRP. In this study, the reactions of N-benzyl and N-methyl cyclic amines with HRP were found to be slow, but reactions of N-(3-indoleethyl) cyclic amines were 2-3 orders of magnitude faster. Analyses of pH-rate profiles revealed a dominant contribution to reaction by the amine-free base forms, the only species found to bind to the enzyme. A metabolic study on a family of congeneric N-(3-indoleethyl) cyclic amines indicated competition between amine and indole oxidation pathways. Amine oxidation dominated for the seven- and eight-membered azacycles, where ring size supports the change in hybridization from sp3 to sp2 that occurs upon one-electron amine nitrogen oxidation, whereas only indole oxidation was observed for the six-membered ring congener. Optical difference spectroscopic binding data and computational docking simulations suggest that all the arylalkylamine substrates bind to the enzyme through their aromatic termini with similar binding modes and binding affinities. Kinetic saturation was observed for a particularly soluble substrate, consistent with an obligatory role of an enzyme-substrate complexation preceding electron transfer. The significant rate enhancements seen for the indoleethylamine substrates suggest the ability of the bound indole ring to mediate what amounts to medium long-range electron-transfer oxidation of the tertiary amine center by the HRP oxidants. This is the first systematic investigation to document aliphatic amine oxidation by HRP at rates consistent with normal metabolic turnover, and the demonstration that this is facilitated by an auxiliary electron-rich aromatic ring.