乙腈体系中咪唑溴盐和电制镁盐协同促进环氧化物与 CO2羧化反应合成环状碳酸酯

CO2是一种储量丰富且廉价易得的可再生 C1资源.以 CO2为原料的羧化反应可将 CO2高效转化成羧酸及其衍生物等高附加值化学品.例如, CO2和环氧化物反应生成环状碳酸酯属于“原子经济”反应,是有效利用 CO2的方法之一,其产物环状碳酸酯广泛用于极性有机溶剂、电池电解液和化妆品等.由于 CO2化学性质非常稳定,不易活化,制备环状碳酸酯的传统方法是以金属卤化物或金属配合物为催化剂在高温高压下进行反应.因此,开发出操作简便且能耗低的绿色技术用于合成环状碳酸酯面临巨大挑战.
　　最近研究表明,电催化技术可使环氧化物和 CO2在温和条件下转化为环状碳酸酯.已报道的电催化反应研究重点都是如何通过多相或均相电催化还原 CO2的方式使环氧化物能够在温和条件下进行羧化反应.然而, CO2电还原生成的 CO2?-自由基非常活泼,在其扩散到溶液中与环氧化物反应之前易在电极上直接转化为 CO和碳酸盐等副产物,从而导致羧化反应较低的电流效率.
　　 Ema课题组报道环氧化物与 CO2羧化反应经历三个步骤,即开环反应、CO2插入反应和闭环反应,其中开环反应活化能最大,是羧化反应决速步骤.与已报道的电催化途径不同,本文通过建立一个由电化学反应和羧化反应组成的催化反应体系,旨在通过降低开环反应活化能来促进环氧化物羧化反应.在电化学反应过程中,由牺牲阳极提供羧化反应必需的路易斯酸,即电制镁盐;在羧化反应过程中,通过电制镁盐和咪唑溴盐的协同作用实现环氧化物和 CO2在温和条件下高效率地转化为环状碳酸酯.
　　实验首先选取环氧苯乙烷为反应原料,考察了电制镁盐、共催化剂的阳离子以及羧化反应温度对目标产物产率的影响.如果羧化反应过程中没有镁盐或直接用等量溴化镁代替电制镁盐,羧化产率仅为5.4%和35.5%,而电制镁盐条件下羧化反应产率高达90.7%,表明电制镁盐作为路易斯酸催化剂对提高羧化反应产率是必不可少的.比较了在 N2和 CO2气氛中分别电解制备得到的镁盐的催化性能. N2气氛中电制镁盐更高的催化性能可能与溶剂乙腈或支持电解质的阳离子在阴极发生电还原生成的物质有关.该电还原产物可部分代替溴离子与电制镁盐配对,由于其体积更大,一定程度上提高了电制镁盐的亲电性,有利于羧化反应进行.如果用四丁基溴化铵代替咪唑溴盐作为共催化剂,羧化反应产率从90.7%降为65.5%.羧化反应过程中溴离子对电制镁盐的配对能力受共催化剂阳离子静电引力的牵制而减弱,共催化剂的阳离子对溴离子的静电引力越强,溴离子对电制镁盐亲电性的影响就越弱.前期研究成果表明,在乙腈溶液中咪唑阳离子对阴离子的静电引力明显强于季铵阳离子,由此可认为当咪唑溴盐作为共催化剂时提高了电制镁盐的亲电性,促进了环氧化物的开环反应.提高羧化反应温度虽然可以降低环氧化物开环反应的活化能,但也会降低 CO2在乙腈溶液中的溶解度,50°C反应较为合适.在最优反应条件下考察了该催化体系对其他环氧化物羧化反应的普适性,所得环状碳酸酯产率为48.3%–90.7%.     

A bifunctional catalyst for carbon dioxide fixation: cooperative double activation of epoxides for the synthesis of cyclic carbonates

We have developed a very active bifunctional porphyrin catalyst showing a high turnover number (TON = 103,000) for the synthesis of cyclic carbonates from CO(2) and epoxides under solvent-free conditions.     

Palladium-catalyzed carbon dioxide elimination-fixation reaction of 4-methoxycarbonyloxy-2-buten-1-ols

A new type of palladium-catalyzed CO(2) recycling reaction using allylic carbonates is described. Reaction of trans-4-methoxycarbonyloxy-2-buten-1-ols in the presence of a palladium catalyst produces cyclic carbonates having a vinyl group via a CO(2) elimination-fixation process. A variety of allylic carbonates participate in the reaction giving cyclic carbonates with high efficiencies. Stereoselective construction of trans-cyclic carbonates is achieved by using nonsymmetric substrates. An enantiospecific reaction proceeds to give chiral cyclic carbonate when a chiral methyl-substituted substrate is subjected to the reaction conditions.     

室温离子液体中二氧化碳与环氧化合物的电催化插入反应

在温和条件下，二氧化碳在室温离子液体中可以被电化学活化。同时，活化后 的二氧化碳在室温离子液体中与环氧化合物发生插入反应生成环状碳酸酯也得到了 较好的结果。[BMIm][BF4]离子液体为反应介质，环氧丙烷为反应底物时得到最佳 反应结果。电化学活化对反应的发生是必需的。     

A novel methodology for the synthesis of cyclic carbonates based on the palladium-catalyzed cascade reaction of 4-methoxycarbonyloxy-2-butyn-1-ols with phenols,involving a novel carbon dioxide elimination-fixation process

A palladium-catalyzed CO(2)-recycling reaction has been developed. Reaction of 4-methoxycarbonyloxy-2-butyn-1-ols with phenols, carried out in the presence of a palladium catalyst, produces phenoxy-substituted cyclic carbonates by way of a pathway involving a CO(2) elimination-fixation. A variety of propargylic alcohols and phenols participate in these reactions which yield cyclic carbonates with high efficiencies. Stereoselective construction of trans-cyclic carbonates is achieved by using nonsymmetric substrates. Highly enantioselective reactions occur when (S)-BINAP is used as a ligand. Reaction of 4-phenoxycarbonyloxy-2-butyn-1-ol in the presence of the palladium catalyst yields the corresponding cyclic carbonates via a three-component decomposition-reconstruction process.     

Direct Synthetic Processes for Cyclic Carbonates from Olefins and CO<Subscript>2</Subscript>

This short review presents the recent developments in the direct synthesis of cyclic carbonates from olefins and CO₂. The straightforward synthesis of cyclic carbonates from olefins instead of epoxides, also called one-pot “oxidative carboxylation” of olefins, can be viewed as the coupling of two sequential reactions of epoxidation of olefins and CO₂ cycloaddition to epoxides formed. The facile synthetic approach would make carbonate synthesis simpler and even cheaper with industrial potential from environmental and economic points of view. Some progresses have been made on this direct synthetic reaction for cyclic carbonates with homogeneous and heterogeneous catalysts, however, this reaction system is still at a preliminary stage. Among the catalysts reported, only a few can be considered as effective for the direct oxidative carboxylation of olefins to cyclic carbonates. Thus active and selective catalysts should be explored to put the direct synthesis of cyclic carbonates into practical applications.     

手性双提蓝钴卟啉配合物催化二氧化碳对环氧的不对称环加成（英文）

绿色化学是当今化学科学研究的前沿领域.仿生催化是绿色合成技术和方法学研究的一个重要方面.生物质和酶分子在酶催化转化过程中的"构-效"关系可以通过仿生催化进行模拟研究.CO_2作为温室气体的主要成分是造成全球气候变暖的主要因素,但它同时也是C1化学的重要原料.利用CO_2与有机环氧化合物通过偶联反应制备有机环碳酸酯或聚碳酸酯则是CO_2化学研究的热点之一,并已经取得了长足的进步.但是运用手性催化剂对此反应进行不对称环加成得到手性环碳酸酯的研究不多.本文首次设计并合成了具有双提篮结构的手性钴卟啉螯合物.其中的提篮部分由手性联萘酚(S或R)和L-苯丙氨酸组成,从卟啉骨架的meso位引入,首先制备了两种手性结构的自由卟啉配体(6a,7a);然后与醋酸钴反应得到两种二价钴卟啉手性配合物(6b,7b),加入醋酸后,通过空气氧化得到三价钴卟啉手性催化剂(6c,7c).采用紫外、红外光谱、质谱和核磁共振(包括二维NMR)等技术对得到的卟啉中间化合物、配合物和催化剂进行了详细的表征,确定了化合物的结构.将得到的三价钴卟啉配合物作为手性催化剂用于CO_2和环氧化合物的不对称环加成反应.结果表明,提篮的手性基团对小分子的环氧化合物环氧丙烷具有手性选择性,在低温-20°C下,可以得到大于50%的ee值.同时由于提篮与卟啉平面空间的有限性,导致分子体积较大的环氧化合物与CO_2的反应很慢,也没有发现其对环碳酸酯的对映选择性.我们相信本工作对于合成手性卟啉分子及其在不对称催化中的应用具有一定的意义.     

Salen-complex-mediated formation of cyclic carbonates by cycloaddition of CO2 to epoxides

Metal complexes of salen ligands are an important class of compounds, and they have been widely studied in the past. Among their successful catalytic applications, the synthesis of cyclic carbonates by the coupling reaction of epoxides with CO(2) has received increased attention; this is mostly due to the importance of using a greenhouse gas as a feedstock for the synthesis of useful molecules. Herein the most relevant past and present research surrounding this topic is presented.     

Development of palladium-catalyzed transformations using propargylic compounds

It is known that propargylic compounds having an ester and a halide at the propargylic positions react with palladium complexes leading to π-propargylpalladium and allenylpalladium complexes, which cause various transformations in the presence of the reactants. The aim of the present study was to develop novel palladium-catalyzed transformations using propargylic compounds. As diastereoselective reactions of propargylic compounds with bis-nucleophiles, we have developed palladium-catalyzed reactions of propargylic carbonates with 2-substituted cyclohexane-1,3-diones, 2-(2-hydroxyphenyl)acetates and 2-oxocyclohex-3-enecarboxylates. These processes produce highly substituted cyclic compounds in a highly stereoselective manner. Through our studies on the construction of substituted 2,3-allenols by the reactions of propargylic oxiranes, it has been made clear that palladium-catalyzed coupling reactions occur in the presence of arylboronic acids and terminal alkynes. The processes can be carried out in mild conditions to yield substituted 4-aryl-2,3-allenols in a diastereoselective manner. In our attempt to develop CO2-recycling reactions, we developed a methodology for the synthesis of cyclic carbonates by palladium-catalyzed reactions of propargylic carbonates with phenols. Our findings suggested that the process proceeds through a pathway involving decarboxylation-followed fixation of the liberated CO2. Diastereoselective, enantioselective, and enantiospecific construction of cyclic carbonates have been achieved by the application of this methodology.     

Experimental and theoretical studies on hydrogen bond-promoted fixation of carbon dioxide and epoxides in cyclic carbonates

The hydrogen bond donor-promoted fixation of CO(2) and epoxides into cyclic carbonates was investigated through experimental and density functional theory studies. A highly effective homogeneous system of 1,2-benzenediol-tetrabutyl ammonium bromide (TBAB) and heterogeneous poly-ionic liquids were developed for the fixation of CO(2) into cyclic carbonates via hydrogen bond activation, based on the understanding of the reaction mechanism and catalyst design. The work hence provides a molecular level understanding of the reaction process and forms the basis for the rational design of catalytic systems for the fixation of CO(2) into useful organic compounds.     

Chemical Fixation of CO2 with Highly Efficient ZnCl/[BMIm]Br Catalyst System

The search for environmentally benign and economic process has been the impetus for much of the research involving epoxide and carbon dioxide coupling in view of the so called "green chemistry" and" atom economy ", since CO2 is a renewable resource and can be used as a safe and cheap C 1 building block to synthesize useful organic compounds without producing any coproducts.[1-2] One of the most attractive synthetic goals starting from carbon dioxide is the chemical fixation of CO2 onto epoxide to afford the five-membered cyclic carbonates (Scheme 1),which are excellent aprotic polar solvents and are used extensively as intermediates in the production of pharmaceuticals and fine chemicals.[3] In the last decades of the twentieth century numerous catalytic systems have been developed for this transformation. While some advances have been obtained, all suffer from either low catalyst stability/reactivity, the need for co-solvent, or the requirement for high pressure and/or catalyst costing expensive.[4] Therefore, to find an effective,not exrensive, environmentally benign and economic catalyst system is urgent.In this paper, chemical fixation of CO2 with mono-substituted terminal epoxides or cyclohexene oxide to form cyclic carbonates under the ZnCl2/[BMIm]Br Catalyst System without using additional organic solvents was achieved in excellent selectivity (＞98%) and TOF(5410h-1) Besides,the pure cis-cyclic carbonate of cyclohexene oxide was obtained in this catalyst system.It was important to note that the catalyst could be recovered by simple vacuum distillation of the corresponding cyclic carbonates and could be used six times almost without losing its catalytic activity and selectivity. The catalyst system was found to be applicable to a variety of terminal epoxides and cyclohexene oxide, forming the corresponding cyclic carbonates in very high TOF and more than 98% selectivity. Based on the obtained results, we also propose the plausible mechanism for this chemical fixation reaction of CO2.     

Palladium‐Catalyzed Asymmetric Allylic Alkylations with Toluene Derivatives as Pronucleophiles

The first two highly enantioselective palladium‐catalyzed allylic alkylations with benzylic nucleophiles, activated with Cr(CO)₃, have been developed. These methods enable the enantioselective synthesis of α‐2‐propenyl benzyl motifs, which are important scaffolds in natural products and pharmaceuticals. A variety of cyclic and acyclic allylic carbonates are competent electrophilic partners furnishing the products in excellent enantioselectivity (up to 99 % ee and 92 % yield). This approach was employed to prepare a nonsteroidal anti‐inflammatory drug analogue.     

Re(CO)5Br-catalyzed coupling of epoxides with CO2 affording cyclic carbonates under solvent-free conditions

In the presence of a catalytic amount of Re(CO)(5)Br, the coupling of epoxides with supercritical CO(2) without an organic solvent at 110 degrees C has afforded cyclic carbonates in good to excellent yields.     

Recent progress in stereoselective synthesis of cyclic organic carbonates and beyond

The recent developments in the stereoselective formation of cyclic organic carbonates are discussed, together with their use as intermediates in stereoselective synthesis of other valuable scaffolds.     

二氧化碳与环氧化合物合成环状碳酸酯的研究进展

二氧化碳作为温室气体和储量大、无毒且可循环利用的碳资源,其化学利用受到了人们的广泛关注. 二氧化碳与环氧化合物通过环加成反应制备环状碳酸酯是二氧化碳化学法利用最为有效的途径之一. 本文综述了近年来该反应的研究进展,讨论了催化剂作用下的反应机理.     

Coupling reactions of CO2 with neat epoxides catalyzed by PPN salts to yield cyclic carbonates

The off-the-shelf reagent PPN+Cl- and PPN-manganese carbonylates [PPN]+[Mn(CO)4L]- (L = CO, PPh3) are good catalysts for the coupling reactions of CO2 with neat epoxides without the use of organic solvents to afford cyclic carbonates. PPN salts with weak nucleophilic anions such as PPN+BF4- and PPN+OTf- are, however, inactive for the coupling reactions.     

Highly Chemoselective Catalytic Coupling of Substituted Oxetanes and Carbon Dioxide

The chemoselective coupling of oxetanes and carbon dioxide to afford functional, heterocyclic organic compounds known as six‐membered cyclic carbonates remains a challenging topic. Here, an effective method for their synthesis relying on the use of Al catalysis is described. The catalytic reactions can be carried out with excellent selectivity for the cyclic carbonate product tolerating various (functional) groups present in the 2‐ and 3‐position(s) of the oxetane ring. The presented methodology is the first general approach towards the formation of six‐membered cyclic carbonates (6MCCs) through oxetane/CO₂ coupling chemistry. Apart from a series of substituted six‐membered cyclic carbonates, also the unprecedented room‐temperature coupling of oxetanes and CO₂ is disclosed giving, depending on the structural features of the substrate, a variety of five‐ and six‐membered heterocyclic products. A mechanistic rationale is presented for their formation and support for the intermediary presence of a carbonic acid derivative is given. The presented functional carbonates may hold great promise as building blocks in organic synthesis and the development of new, biodegradable polymers.     

Tubular microporous organic networks bearing imidazolium salts and their catalytic CO2 conversion to cyclic carbonates

Tubular microporous organic networks bearing imidazolium salts (T-IM) were prepared by Sonogashira coupling of tetrakis(4-ethynylphenyl)methane and diiodoimidazolium salts, which showed promising catalytic activities in heterogeneous conversion of CO(2) into cyclic carbonates.     

Utilisation of CO2 as a chemical feedstock: opportunities and challenges

The need to reduce the accumulation of CO(2) into the atmosphere requires new technologies able to reduce the CO(2) emission. The utilization of CO(2) as a building block may represent an interesting approach to synthetic methodologies less intensive in carbon and energy. In this paper the general properties of carbon dioxide and its interaction with metal centres is first considered. The potential of carbon dioxide as a raw material in the synthesis of chemicals such as carboxylates, carbonates, carbamates is then discussed. The utilization of CO(2) as source of carbon for the synthesis of fuels or other C(1) molecules such as formic acid and methanol is also described and the conditions for its implementation are outlined. A comparison of chemical and biotechnological conversion routes of CO(2) is made and the barriers to their exploitation are highlighted.     

New mechanistic insight into the coupling reactions of CO2 and epoxides in the presence of zinc complexes

Coupling reactions of CO(2) and epoxide to produce cyclic carbonates were performed in the presence of a catalyst [L(2)ZnX(2)] (L=pyridine or substituted pyridine; X=Cl, Br, I), and the effects of pyridine and halide ligands on the catalytic activity were investigated. The catalysts with electron-donating substituents on pyridine ligands exhibit higher activity than those with unsubstituted pyridine ligands. On the other hand, the catalysts with electron-withdrawing substituents at the 2-position of the pyridine ligands show no activity; this demonstrates the importance of the basicity of the pyridine ligands. The catalytic activity of [L(2)ZnX(2)] was found to decrease with increasing electronegativity of the halide ligands. A series of highly active zinc complexes bridged by pyridinium alkoxy ions of the general formula [((mu-OCHRCH(2)L)ZnBr(2))(n)] (n=2 for R=CH(3); n=3 for R=H; L=pyridine or substituted pyridine) were synthesized and characterized by X-ray crystallography. The dinuclear zinc complexes obtained from propylene oxide adopt a square-planar geometry for the Zn(2)O(2) core with two bridging pyridinium propoxy ion ligands. Trinuclear zinc complexes prepared from ethylene oxide adopt a boat geometry for the Zn(3)O(3) core, in which three zinc and three oxygen atoms are arranged in an alternate fashion. These zinc complexes bridged by pyridinium alkoxy ions were also isolated from the coupling reactions of CO(2) and epoxides performed in the presence of [L(2)ZnBr(2)]. Rapid CO(2) insertion into the zincbond;oxygen bond of the zinc complexes bridged by pyridinium alkoxy ions leads to the formation of zinc carbonate species; these which yield cyclic carbonates and zinc complexes bridged by pyridinium alkoxy ions upon interaction with epoxides. The mechanistic pathways for the formation of active species and cyclic carbonates are discussed on the basis of results from structural and spectroscopic analyses.