超临界二氧化碳介质中溴化钯催化炔烃环三聚反应

研究了以超临界二氧化碳为反应介质溴化钯催化炔烃环三聚反应的新方法.研究结果表明:二氧化碳介质中使用溴化钯为催化剂可以顺利地催化炔烃发生环三聚反应,区域选择性生成含苯环芳香族化合物.     

钯催化的炔烃芳构化反应研究

综述了钯络合物催化的炔烃环三聚芳构化反应的历史沿革及最新研究进展,并结合该研究小组的工作,重点阐述了钯催化炔烃 [ 2+2+2 ] 环三聚芳构化、双炔烃、共轭烯炔 [ 4+2 ] 芳构化反应。同时对反应的几种典型催化体系和反应机理,以及该领域的一些前沿热点也作了综述。     

《有机化学》总目次

钯催化的炔烃环三聚反应.....................................................................................................................................................................................................................周磊江焕峰*黄精美唐金玉(1)亚甲胺叶立德参与的[3 2]环加成反应的最新进展....................................................................................................................................................................................................…     

钯催化的炔烃环三聚反应

综述了两种不同价态的钯(零价、二价)催化的炔烃环三聚反应及其最新研究进展, 重点讨论配体、溶剂、取代基等对反应的化学选择性和区域选择性的影响, 并对其中一种较新颖的[2＋2＋1]型环三聚反应、作用机理及所遇到的挑战给予介绍.     

超临界二氧化碳中羰基钴催化的端基炔烃环三聚反应研究

原子经济性良好的炔烃[2+2+2]环加成反应与绿色溶剂超临界二氧化碳相结合,是一个符合绿色化学原则的环境友好反应过程.建立了一个纯超临界二氧化碳介质中八羰基二钴催化的端基炔烃环三聚反应体系,在优化的反应条件下,以较高产率选择性地制备1,2,4-三取代苯衍生物.优化了催化剂用量、二氧化碳压力、反应温度及时间等反应条件,讨论了反应物料及催化剂在超临界二氧化碳介质中的溶解性和相行为,提出了端基炔烃环三聚反应机理,并将反应底物从C≡C键拓展至C≡N键,对超临界二氧化碳介质中炔-腈环加成反应进行了初步探索.优化出的炔烃环三聚催化反应体系无需使用有机助溶剂和各类助剂,底物适应性好,产物选择性高,为合成1,2,4-三取代苯衍生物提供了一种绿色合成方法.     

过渡金属催化炔烃环化反应的研究进展

具有独特反应性和稳定性的炔烃类化合物一直以来是科研工作者们关注的热点之一,其中关于炔烃环化构筑一系列多环化合物的反应报道尤为突出。本文根据不同金属催化剂,总结归纳了近几年铑、钌、钴、钯等过渡金属催化炔烃环化反应的研究进展,并简要讨论了催化转化的反应机理、优势以及局限性,最后展望了过渡金属催化炔烃环化反应的发展前景。     

钌催化二环烯烃与炔烃的[2＋2]环加成反应的研究进展

综述了近年来钌催化二环烯烃与炔烃发生[2＋2]环加成反应的研究进展, 重点讨论了钌催化二环烯烃和炔烃的 [2＋2]环加成反应中反应物结构、反应物比例、溶剂及温度等因素对反应的影响.     

一种温和高效的钯催化乙炔的环三聚

乙炔是石油化工的重要产品之一,乙炔分子中存在高活性的π电子体系,具有很高的反应活性。许多催化体系包括过渡金属催化剂、非金属催化剂等可以催化活泼的乙炔发生环三聚反应,得到重要的化工原料苯。作者首次利用氯化钯作为催化剂催化乙炔环三聚,在很温和的条件下高效率地实现了这一反应。     

过渡金属催化的炔烃复分解反应

综述了过渡金属均相催化的炔烃复分解反应进展,主要分为两部分：一是炔烃复分解反应在炔烃合成中的应用,即从六、七十年代Mortreux催化剂的发现能均相催化炔烃的歧化反应,经过一系列的条件改造,合成了炔醚和二芳基乙炔等化合物,并提出了可能的两种机理：金属卡宾和金属卡拜机理;金属钼和钨的卡拜络合物相继合成,发现此类络合物能够催化官能化的二炔的复分解反应,合成一系列的大环化合物。二是炔烃复分解反应在合成高聚物中的应用,即钙和钨的卡拜络合物被用来催化ROMP和ADIMET反应合成高聚物,改良了的Mortreux催化剂也能催化高聚物的生成,这些高聚物在发光器件、有机"塑料"激光、液晶显示器上都有应用。     

环张力促进的叠氮-炔环加成反应

近年来,点击化学中的环张力促进的叠氮-炔环加成(SPAAC)反应由于具有高效快速、高选择性和生物正交性等优点被广泛用于生物医学和材料科学等多个领域。SPAAC反应不需要光、热、超声和催化剂等额外的刺激,反应的驱动力来源于高张力的活泼环状炔烃,因此合理设计环状炔烃是SPAAC反应的关键。本文详细归纳了不同环数目的环状炔烃的稳定性和反应活性,总结参与SPAAC的稳定环状炔烃,并讨论了它们参与SPAAC反应的二级反应速率常数。本文还介绍了目前应用广泛的代表性环状炔烃的制备方法研究进展。最后,对无铜催化的SPAAC的应用前景和存在的问题进行讨论和展望。     

Novel Role of Carbon Dioxide as a Selective Agent in Palladium-Catalyzed Cyclotrimerization of Alkynes

Carbon dioxide was found as a selective agent to promote the palladium-catalyzed cyclotrimerization of alkynes in water. Both aryl and alkylacetylenes afforded the corresponding cyclotrimerization products regioselectively in high yields using PdCl2, CuCl2, and CO2 as the catalytic system. However, tert-butylacetylene bearing a bulky group gave a dimerization product. Mechanism of this reaction was also discussed.     

Chemo- and regioselective intermolecular cyclotrimerization of terminal alkynes catalyzed by cationic rhodium(I)/modified BINAP complexes: application to one-step synthesis of paracyclophanes

A highly regioselective intermolecular cyclotrimerization of terminal alkynes has been developed based on the use of the cationic rhodium(I)/DTBM-Segphos complex. This method can be applied to a variety of terminal alkynes to provide 1,2,4-trisubstituted benzenes in high yield and with high regioselectivity. A chemo- and regioselective intermolecular crossed-cyclotrimerization of dialkyl acetylenedicarboxylates with a variety of terminal alkynes has also been developed based on the use of the cationic rhodium(I)/H8-BINAP complex, furnishing 3,6-disubstituted phthalates in high yields. It constitutes a highly efficient new method for intermolecular crossed-cyclotrimerization of two different monoynes in terms of catalytic activity, chemo- and regioselectivity, scope of substrates, and ease of operation. The versatility of this new crossed-alkyne cyclotrimerization procedure is demonstrated through its application to one-step synthesis of a [6]metacyclophane and [7]-[12]paracyclophanes from the corresponding terminal alpha,omega-diynes. Mechanistic studies have revealed that the chemo- and regioselectivity of this crossed-alkyne cyclotrimerization are determined by the preferential formation of a specific rhodium metallacycle derived from a terminal alkyne and a dialkyl acetylenedicarboxylate.     

CpRuCl- and CpCo-catalyzed or mediated cyclotrimerizations of alkynes and [2+2+2] cycloadditions of alkynes to alkenes: A comparative DFT study

Computational methods have been used to better understand both the CpRuCl- and CpCo-catalyzed and mediated cyclotrimerization of alkynes and the [2+2+2] cycloaddition of alkynes to alkenes. These studies have allowed more accurate mechanisms to be proposed for each of these transformations and for some previously proposed intermediates to be discarded. The mechanistic rationale of these processes depends on the nature of the metal, ligands and substrate partners.     

A mechanistic study of the utilization of arachno-diruthenaborane [(Cp*RuCO)2B2H6] as an active alkyne-cyclotrimerization catalyst

The reaction of nido-[1,2-(Cp*RuH)(2)B(3)H(7)] (1a, Cp*=η(5)-C(5)Me(5)) with [Mo(CO)(3)(CH(3)CN)(3)] under mild conditions yields the new metallaborane arachno-[(Cp*RuCO)(2)B(2)H(6)] (2). Compound 2 catalyzes the cyclotrimerization of a variety of internal- and terminal alkynes to yield mixtures of 1,3,5- and 1,2,4-substituted benzenes. The reactivities of nido-1a and arachno-2 with alkynes demonstrates that a change in geometry from nido to arachno drives a change in the reaction from alkyne-insertion to catalytic cyclotrimerization, respectively. Density functional calculations have been used to evaluate the reaction pathways of the cyclotrimerization of alkynes catalyzed by compound 2. The reaction involves the formation of a ruthenacyclic intermediate and the subsequent alkyne-insertion step is initiated by a [2+2] cycloaddition between this intermediate and an alkyne. The experimental and quantum-chemical results also show that the stability of the metallacyclic intermediate is strongly dependent on the nature of the substituents that are present on the alkyne.     

Highly chemo- and regioselective intermolecular cyclotrimerization of alkynes catalyzed by cationic rhodium(I)/modified BINAP complexes

[reaction: see text] Cationic rhodium(I)/modified BINAP complexes are effective catalysts for highly regioselective intermolecular cyclotrimerization of terminal alkynes and highly chemo- and regioselective intermolecular cocyclotrimerization of diethyl acetylenedicarboxylate (DEAD) and terminal alkynes. It is a noteworthy example of intermolecular cocyclotrimerization of two different alkynes in terms of catalytic activity, chemo- and regioselectivity, scope of substrates, and ease of operation. The wide applicability of this new cocyclotrimerization procedure is demonstrated in the one-step synthesis of [6]metacyclophane.     

Methylidynetricobalt nonacarbonyl catalyzed cyclotrimerization of alkynes

A cobalt carbonyl cluster, methylidynetricobalt nonacarbonyl, catalyzed inter- and intramolecular cyclotrimerization of alkynes producing substituted benzene derivatives in good to excellent yields.     

Nickel‐Catalyzed Facile [2+2+2] Cyclotrimerization of Unactivated Internal Alkynes to Polysubstituted Benzenes

A catalytic [2+2+2] cyclotrimerization of unactivated internal alkynes providing cyclotrimerization products in excellent yields with high regioselectivity is described. The transformation is accomplished by using a simple catalytic mixture comprising Ni(acac)₂, an imidazolium salt and a Grignard reagent at room temperature or 60 °C for 20 min or 1 h.     

A simple PdCl2/O2/DMF catalytic system for highly regioselective cyclotrimerization of olefins with electron-withdrawing groups

A highly regioselective cyclotrimerization of olefins with electron-withdrawing groups in a PdCl₂/O₂/DMF catalytic system is disclosed, and a possible mechanism has also been proposed, which reveals the PdCl₂-catalyzed cyclotrimerization of olefins with electron-withdrawing groups goes through a quite different pathway from that of alkynes.