有机钼、钨化合物的研究(Ⅲ)——含σ-键的钼、钨络合物对取代乙炔的催化聚合作用

前文曾报导Fischer型钼的卡宾络合物对炔烃的催化聚合作用比钨的卡宾络合物高。含有σ-键的钼、钨络台物对炔烃的催化聚合作用,至今未见报导。我们按文献合成了四个含σ-键的钼、钨络合物,试验了它们对炔烃的催化聚合作用。 实验部分     

过渡金属催化炔类高分子合成进展

过渡金属催化反应的蓬勃发展有力地推动了结构多样、功能丰富的炔类高分子的合成和应用研究.从炔烃单体出发合成炔类高分子经典的策略包括：(1)炔基碳氢(卤)键活化,对应偶联聚合;(2)金属卡拜或卡宾对碳碳三键的活化,对应复分解聚合.最近,我们课题组的工作引入了第三种模式,即通过炔丙位化学键的活化,形成联烯基金属物种,进而介导累积烯烃的原位生成并链式聚合,得到炔烃主链.本专论围绕以上3种反应模式,论述近年来具有代表性的炔类高分子合成方法新发展,并从机理的角度重点讨论新兴的链式聚合方法.     

分子内烯炔复分解反应研究进展

烯炔复分解反应涉及碳-碳双键和叁键的断裂及重组生成1,3-二烯烃化合物.分子内的烯炔复分解反应已成为合成各种环状化合物的有用方法.主要介绍了分子内烯炔复分解反应的机理,催化剂以及Ru卡宾催化的烯炔复分解反应在有机合成中的应用.     

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。     

金属卡拜的合成与反应

自1973年Fischer E O及其合作者报道了第一例金属卡拜(金属-碳叁键物种)后,金属卡拜的研究得到了较快发展.基于独特的金属-碳叁键,金属卡拜可作为一类新型试剂/活性中间体参与到有机反应中,并可作为催化剂实现炔烃复分解等转化反应.本文简述了金属卡拜的合成方法及其在当量反应和催化反应中的应用.     

三价钴催化下N-S键辅助的非氧化条件下经碳氢活化合成异喹啉

异喹啉是非常重要的杂环化合物,广泛应用于有机合成中,也是构成药物和材料分子的核心骨架。很多异喹啉类的生物碱都由异喹啉基本骨架构成,它们都有一定药理活性和生物活性,包括抗真菌、抗癌、抗心律失常、阵痛麻醉和降血压等功效。迄今已知的含异喹啉骨架的生物碱超过1000种,是生物碱中最多的一类。传统的合成异喹啉的方法需要官能化的原料和强酸,反应条件比较苛刻,合成步骤繁琐。例如Larock课题组利用钯催化将邻溴官能化的亚胺与炔烃环化偶联,合成了一系列异喹啉化合物。而过渡金属催化合成异喹啉是一种能够有效合成多种取代基异喹啉的方法。在过去的几十年中,通过碳氢活化策略合成杂环化合物的方法得到迅猛发展,从而使得大量的芳基化合物都能作为反应的起始原料。尤其是铑、铱、钯、钌等过渡金属都能催化芳烃的碳氢活化,从而合成异喹啉化合物。 Fagnou课题组最早报道了氧化条件下利用三价铑催化剂经碳氢键活化与炔烃偶联合成异喹啉的方法。随后,众多研究组利用氧化型导向基策略在无外加氧化剂条件下高效、高选择性地合成了异喹啉。除了利用三价铑催化剂之外,利用二价钌催化剂通过碳氢活化策略也能实现类似反应。但是,这些反应体系都必须使用铑和钌等贵金属催化剂,极大地限制了该合成异喹啉方法的应用前景。近年来,数个研究组将地球上储量丰富、便宜有效的钴络合物作为催化剂应用到芳烃的碳氢键活化反应中,在简单的反应条件下合成了各种杂环化合物。对于一些反应,三价钴催化与三价铑催化能形成互补。最近, Kanai, Ackermann和Sundararaju几乎同时报道了三价钴催化肟谜的碳氢键活化,并在无外加氧化剂条件下实现了其与炔烃的偶联反应,高效地合成了异喹啉,在该类反应中以氮–氧键断裂作为内部氧化剂。但是在钴催化条件下氧化性的氮–硫键作为内部氧化剂辅助碳氢键活化的反应尚无报道。本课题组最近报道了芳基酮的N-亚磺酰亚胺与烯烃和胺化试剂的偶联反应,经N–S键断裂,高效合成了喹唑啉。本文利用三价钴催化剂在无外加氧化剂条件下实现了芳基酮N-亚磺酰亚胺与炔烃的偶联,反应经历了碳氢键活化和氮硫键断裂得到异喹啉。此反应对端炔和内炔底物均适用。为了初步了解反应机理,我们利用分子内竞争的方法进行了动力学同位素效应测定,结果表明碳氢键断裂过程可能是反应的决速步骤。结合文献结果,提出了可能的反应机理。     

末端炔烃二聚反应合成共轭烯炔的研究进展

综述了不同催化体系催化末端炔烃二聚反应合成共轭烯炔化合物的研究进展. 其中催化体系主要包括过渡金属配合物、镧系和锕系金属配合物、第三主族元素配合物以及有机催化剂. 实验结果表明: 不同催化体系对末端炔烃二聚反应的选择性控制有影响, 尤其是区域选择性(头-头二聚或头-尾二聚).     

CuI/DEAD促进的端炔的二聚偶联反应

端炔烃的二聚偶联反应是合成含有共轭碳碳叁键化合物的一个重要方法.在CuI的催化下,以催化量的N-甲基咪唑为碱,在偶氮二甲酸二乙酯(DEAD)的协助下,各种不同的芳香族和脂肪族端炔都能顺利的发生二聚Glaser偶联反应.考察了不同铜催化剂和溶剂对该反应的影响.反应具有收率高、操作简单、条件温和等优点.     

三价钴催化下N–S键辅助的非氧化条件下经碳氢活化合成异喹啉（英文）

异喹啉是非常重要的杂环化合物,广泛应用于有机合成中,也是构成药物和材料分子的核心骨架.很多异喹啉类的生物碱都由异喹啉基本骨架构成,它们都有一定药理活性和生物活性,包括抗真菌、抗癌、抗心律失常、阵痛麻醉和降血压等功效.迄今已知的含异喹啉骨架的生物碱超过1000种,是生物碱中最多的一类.传统的合成异喹啉的方法需要官能化的原料和强酸,反应条件比较苛刻,合成步骤繁琐.例如Larock课题组利用钯催化将邻溴官能化的亚胺与炔烃环化偶联,合成了一系列异喹啉化合物.而过渡金属催化合成异喹啉是一种能够有效合成多种取代基异喹啉的方法.在过去的几十年中,通过碳氢活化策略合成杂环化合物的方法得到迅猛发展,从而使得大量的芳基化合物都能作为反应的起始原料.尤其是铑、铱、钯、钌等过渡金属都能催化芳烃的碳氢活化,从而合成异喹啉化合物.Fagnou课题组最早报道了氧化条件下利用三价铑催化剂经碳氢键活化与炔烃偶联合成异喹啉的方法.随后,众多研究组利用氧化型导向基策略在无外加氧化剂条件下高效、高选择性地合成了异喹啉.除了利用三价铑催化剂之外,利用二价钌催化剂通过碳氢活化策略也能实现类似反应.但是,这些反应体系都必须使用铑和钌等贵金属催化剂,极大地限制了该合成异喹啉方法的应用前景.近年来,数个研究组将地球上储量丰富、便宜有效的钴络合物作为催化剂应用到芳烃的碳氢键活化反应中,在简单的反应条件下合成了各种杂环化合物.对于一些反应,三价钴催化与三价铑催化能形成互补.最近,Kanai,Ackermann和Sundararaju几乎同时报道了三价钴催化肟谜的碳氢键活化,并在无外加氧化剂条件下实现了其与炔烃的偶联反应,高效地合成了异喹啉,在该类反应中以氮–氧键断裂作为内部氧化剂.但是在钴催化条件下氧化性的氮–硫键作为内部氧化剂辅助碳氢键活化的反应尚无报道.本课题组最近报道了芳基酮的N-亚磺酰亚胺与烯烃和胺化试剂的偶联反应,经N–S键断裂,高效合成了喹唑啉.本文利用三价钴催化剂在无外加氧化剂条件下实现了芳基酮N-亚磺酰亚胺与炔烃的偶联,反应经历了碳氢键活化和氮硫键断裂得到异喹啉.此反应对端炔和内炔底物均适用.为了初步了解反应机理,我们利用分子内竞争的方法进行了动力学同位素效应测定,结果表明碳氢键断裂过程可能是反应的决速步骤.结合文献结果,提出了可能的反应机理.     

金属催化合成呋喃衍生物的最新进展

综述了近几年来利用金属催化合成多取代呋喃环的方法。分两大类介绍：一是通过对呋喃环进行结构改造,即呋喃金属试剂在过渡金属催化下与卤化物或酰氯发生偶联反应得到,或呋喃卤化物与金属试剂、烯烃、炔烃偶联得到;二是以非环状化合物为前体进行呋喃环的构筑,即在金属试剂催化下,1,2-联烯基酮、β-碘代-β-烯酮、叁键在α,β-、β,γ-、γ,δ-的炔酮、4-炔-2-烯醇可以关环得到多取代的呋喃产物。此外,在Ru~2(OAc)~4催化下,α-叠氮酮与炔烃反应得到金属卡宾中间体,然后关环也可得到取代呋喃产物。     

Copper‐Catalyzed Aerobic Oxidative Transformation of Ketone‐Derived N‐Tosyl Hydrazones: An Entry to Alkynes

A novel strategy involving Cu‐catalyzed oxidative transformation of ketone‐derived hydrazone moiety to various synthetic valuable internal alkynes and diynes has been developed. This method features inexpensive metal catalyst, green oxidant, good functional group tolerance, high regioselectivity and readily available starting materials. Oxidative deprotonation reactions were carried out to form internal alkynes and symmetrical diynes. Cross‐coupling reactions of hydrazones with halides and terminal alkynes were performed to afford functionalized alkynes and unsymmetrical conjugated diynes. A mechanism proceeding through a Cu‐carbene intermediate is proposed for the C? C triple bond formation.     

以N-杂环卡宾为配体的金属络合物催化有机合成的反应

综述了近几年来以N-杂环卡宾为配体的金属络合物催化有机合成的反应。     

Well-Defined Alkyne Metathesis Catalysts: Developments and Recent Applications

Although alkyne metathesis has been known for 50 years, rapid progress in this field has mostly occurred during the last two decades. In this article, the development of several highly efficient and thoroughly studied alkyne metathesis catalysts is reviewed, which includes novel well-defined, in situ formed and heterogeneous systems. Various alkyne metathesis methodologies, including alkyne cross-metathesis (ACM), ring-closing alkyne metathesis (RCAM), cyclooligomerization, acyclic diyne metathesis polymerization (ADIMET), and ring-opening alkyne metathesis polymerization (ROAMP), are presented, and their application in natural product synthesis, materials science as well as supramolecular and polymer chemistry is discussed. Recent progress in the metathesis of diynes is also summarized, which gave rise to new methods such as ring-closing diyne metathesis (RCDM) and diyne cross-metathesis (DYCM).     

Retracted: A Facile Synthetic Route to New Fluorinated Building‐Blocks of 1‐Fluoroalkynes and 1‐Fluorodiynes

A facile and direct fluorination process of alkynes and diynes was developed. In the presence of n‐butyllithium, the reaction of a series of terminal alkynes and diynes with the electrophilic fluorinating reagent (NFSI) proceeded to afford various 1‐fluoroalkynes and 1‐fluoro‐1,3‐diynes in moderate to high yields.     

Rh(I)-catalyzed coupling cyclization of N-aryl trifluoroacetimidoyl chlorides with alkynes: one-pot synthesis of fluorinated quinolines

[reaction: see text]. Rh(I) complexes were found to catalyze the coupling cyclization of N-aryl trifluoroacetimidoyl chlorides with alkynes to afford 2-trifluoromethylated quinolines in good yields. Various alkynes were applied to this cyclization coupling with regioselectivity.     

Trends in Ring-Opening Metathesis Polymerization

Abstract

Several transition metal alkylidene complexes are first discussed as catalysts for the ring-opening metathesis reaction. A new ruthenium catalyst with a slightly enhanced reaction rate is introduced. The stereochemistry and kinetics of the catalysts are investigated with different norbornene derivatives. Then it is shown that MgCl₂ alone is a good heterogeneous catalyst for the ring-opening polymerization (ROMP) of norbornene compounds. This is the first catalyst which does not need activation by a transition metal compound or another organometallic cocatalyst. Applications of the ROMP reaction for the synthesis of polymer specialities covering conjugated liquid crystals and optically active polymers are shown. Poly(cyclopentadienylene vinylene) and sidechain liquid crystal polymers are discussed in more detail. Finally, the synthesis of liquid crystalline elastomers by incorporation of bifunctional monomers during the ROMP reaction is described. It is shown that this kind of polymer can be used for the fabrication of optically anisotropic materials.     

1,3-Diyne chemistry: synthesis and derivations

Conjugated diynes have attracted more and more attention not only for their unique rod like structures and wide existence in nature product, but also the abundant properties and derivations of them. Although oxidative dimerization of alkynes or Cadiot–Chodkiewicz reactions were the main pathway and have achieved great success in the synthesis of diynes, oxidative cross coupling, FBW rearrangement as well as diyne metathesis emerged rapidly recently. Moreover, diynes could be precursors of basic heterocycles, which represented an emerging research area. This Letter will cover the recent progresses in the synthesis and further derivations of diynes.     

Enantioselective synthesis of cyclic secondary amines through Mo-catalyzed asymmetric ring-closing metathesis (ARCM)

Carbocyclic amines are synthesized efficiently in up to 93% ee by asymmetric ring-closing metathesis (ARCM) with 2-5 mol % chiral Mo complexes. An example is provided where the catalyst is prepared in situ (catalyst isolation not needed) to afford secondary amines that cannot be prepared by alternative methods. [reaction: see text]     

N‐Heterocyclic Carbene,High Oxidation State Molybdenum Alkylidene Complexes: Functional‐Group‐Tolerant Cationic Metathesis Catalysts

We synthesized the first N‐heterocyclic carbene (NHC) complexes of Schrock’s molybdenum imido alkylidene bis(triflate) complexes. Unlike existing bis(triflate) complexes, the novel 16‐electron complexes represent metathesis active, functional‐group‐tolerant catalysts. Single‐crystal X‐ray structures of two representatives of this novel class of Schrock catalysts are presented and reactivity is discussed in view of their structural peculiarities. In the presence of monomer (substrate), these catalysts form cationic species and can be employed in ring‐closing metathesis (RCM), ring‐opening metathesis polymerization (ROMP), as well as in the cyclopolymerization of α,ω‐diynes. Monomers containing functional groups, which are not tolerated by the existing variations of Schrock’s catalyst, e.g., sec‐amine, hydroxy, and carboxylic acid moieties, can be used. These catalysts therefore hold great promise in both organic and polymer chemistry, where they allow for the use of protic monomers.     

An improved catalyst for ring-closing alkyne metathesis based on molybdenum hexacarbonyl/2-fluorophenol

[reaction: see text] An improved "instant" catalyst for ring-closing alkyne metathesis reaction is described. Catalyst formed in situ from molybdenum hexacarbonyl and 2-fluorophenol can be used without exclusion of air and moisture and shows high activity in metathesis of functionalized diynes. This system allows cyclization of substrates which were incompatible with previously known Mo(CO)(6)/phenol catalysts.