Electrocarboxylation of benzyl halides through redox catalysis on the preparative scale

The electrocarboxylation of benzyl halides to the corresponding carboxylic acids through homogeneous charge-transfer catalysis was investigated both theoretically and experimentally to determine the influence of the operative parameters on the yield of the process and on the catalyst consumption. Theoretical considerations, based on fast kinetics of redox catalysis, were confirmed by the electrocarboxylation of 1-phenyl-1-chloroethane catalyzed by 1,3-benzenedicarboxylic acid dimethyl ester performed at a carbon cathode under different operative conditions. We obtained high yields of the target carboxylic acid and experienced a low catalyst consumption by operating with optimized [RX]bulk/[CO2]bulk and [RX]bulk/[catalyst] ratios.     

Homogeneous redox catalysis of multielectron electrochemical reactions: Part II. Competition between homogeneous electron transfer and addition on the catalyst

Homogeneous redox catalytic processes in which catalysis competes with partial destruction of the catalyst are investigated. The kinetics are shown to depend upon three parameters: the excess factor (concentration of substrate over concentration of the catalyst), a dimensionless kinetic parameter representing the rate of the initial homogeneous electron transfer step and a dimensionless parameter representing the competition between the second electron transfer and the addition on the catalyst. Procedures are described that allow the rate constant of the initial electron transfer step and the ratio of the rate constants of the second electron transfer vs. the addition step to be extracted from the experimental data. The reduction of n-butyl chloride and bromide, mediated by aromatic anion radicals, is taken as an example illustrating the application of the proposed procedures to experimental systems.     

Main group redox catalysis: reversible P(III)/P(V) redox cycling at a phosphorus platform

A planar, trivalent phosphorus compound is shown to undergo reversible two-electron redox cycling (P(III)/P(V)) enabling its use as catalyst for a transfer hydrogenation reaction. The trivalent phosphorus compound activates ammonia-borane to furnish a 10-P-5 dihydridophosphorane, which in turn is shown to transfer hydrogen cleanly to azobenzene, yielding diphenylhydrazine and regenerating the initial trivalent phosphorus species. This result constitutes a rare example of two-electron redox catalysis at a main group compound and suggests broader potential for this nonmetal platform to support bond-modifying redox catalysis of the type dominated by transition metal catalysts.     

Highly Efficient and Stereoselective Thioallylation of Alkynes: Possible Gold Redox Catalysis with No Need for a Strong Oxidant

Stereoselective thioallylation of alkynes under possible gold redox catalysis was accomplished with high efficiency (as low as 0.1 % catalyst loading, up to 99 % yield) and broad substrate scope (various alkynes, inter‐ and intramolecular fashion). The gold(I) catalyst acts as both a π‐acid for alkyne activation and a redox catalyst for Au^I/III coupling, whereas the sulfonium cation generated in situ functions as a mild oxidant. This novel methodology provides an exciting system for gold redox catalysis without the need for a strong oxidant.     

Charge-transfer complexes in homogeneous catalysis

It is shown that these complexes can be formed between the reactants in redox reactions. Oxidizing and reducing agents are classified on the basis of charge-transfer capacity, which is defined by the integral for the overlap between the filled orbital of the reductant and the free one of the oxidant. Unfilled diffuse d-orbitals most readily give such complexes. Homogeneous catalysis of a redox reaction involves charge transfer in either direction between the catalyst (which has partly filled d-orbitals) and one of the reagents. The transfer is very much dependent on the orientation, so activators play a large part.     

Kinetics and mechanism of 4-acetoxytoluene oxidation by ozone in an acetic anhydride solution in the presence of manganese bromide catalysts

The kinetics of the reaction of ozone with 4-acetoxytoluene in an acetic anhydride solution in the presence of a manganese bromide catalyst is reported. Under these conditions, the major reaction products are 4-acetoxybenzylidenediacetate (68.0%), 4-acetoxybenzyl acetate (18.5%), and 4-acetoxybenzyl bromide (1.6%). The effect of manganese(II) acetate and potassium bromide on the selectivity of oxidation at the methyl group has been investigated. A probable redox catalysis mechanism explaining the experimental data is considered.     

Mechanistic Study of Catalysis in the Mizoroki–Heck Reaction with Anhydrides of Aromatic Acids

A kinetic study of reaction of alkene arylation by anhydrides of aromatic acids (modified Mizoroki–Heck reaction) was carried out using differential selectivity as the main measured parameter. The results obtained under conditions of competition between a pair of alkenes or a pair of aromatic anhydrides point to the occurrence of the reaction via a homogeneous mechanism of catalysis analogously to a conventional variant of reaction with aryl halides as arylating reagents. The hypothesis that the active catalyst is homogeneous agrees with the results of kinetic studies of processes of catalyst formation and deactivation.     

Catalysis of electrochemical reactions at derivatized electrodes: Kinetic model for stationary voltammetric techniques and preparative scale electrolysis

Catalysis of electrochemical reactions at derivatized electrode surfaces may offer an attractive alternative to homogeneous catalysis as far as problems related to separation between catalyst and product and to minimizing the required amount of catalyst are concerned. In this context, several points are addressed regarding catalysis at a monolayer derivatized electrode: (1) catalytic efficiency in terms of preparative scale electrolysis and effect of side reactions destroying the active form of the catalyst;(2) comparison between monolayer derivatized electrode and homogeneous catalysis for systems having the same activation free energy; (3) the problem of redox (outer-sphere) catalysis at monolayer derivatized electrodes compared to naked conventional electrodes is discussed in terms of the current theories of adiabatic outer-sphere electron transfer involving the possible effects of collision frequency factors, image force energy and electrostatic work terms.     

废油脂催化转化制取生物柴油的研究

随着世界经济的发展,石化燃料已经不能满足世界经济发展的需要.以天然油脂为原料生产的生物柴油,作为一种可再生的清洁能源,目前已经受到世界各国的普遍关注.但是目前生产生物柴油使用最广泛的原料是纯菜籽油,生产成本较高,不具有与石化柴油竞争的能力.因此,本实验提出了利用餐     

低温等离子体催化消除炭烟的研究进展

利用低温等离子体的非热力学平衡特性,在较低温度下将氧气分子转化为活性氧物种,从而将炭烟氧化消除,其炭烟消除速率和CO₂选择性等受等离子体放电结构、能量密度、反应气氛和催化剂的影响。本文对低温等离子体氧化消除炭烟的研究进展进行了总结,探讨反应器结构、能量密度、气相组成及催化剂对低温等离子体催化消除炭烟性能的影响规律,总结低温等离子体与催化剂协同催化机理的研究进展,分析低温等离子体与催化剂协同催化消除炭烟的主要挑战和发展趋势。     

Oxidation of 2-acetoxytoluene with ozone in acetic anhydride

Kinetics and mechanism of the reaction of ozone with 2-acetoxytoluene in acetic anhydride in the presence of sulfuric acid were studied. It was shown that the prevailing reaction route under these conditions is ozonolysis (89%), and the selectivity of the oxidation of the substrate by the methyl group is no higher 9%. However, in the presence of manganese(II) sulfate as a catalyst, the selectivity increases to 76%. The major reaction products were 2-acetoxybenzyl acetate (59%) and 2-acetoxybenzylidene diacetate (17%). In the presence of a manganese bromide catalyst, the oxidation depth increases, and the major reaction product is already 2-acetoxybenzylidene (66%), while the yield of 2-acetoxybenzyl acetate is 15%. The mechanism of the redox catalysis is considered, that explains the experimental results.     

CuII‐Catalyzed Oxidative Formation of 5‐Alkynyltriazoles

In an alcoholic solvent under the catalysis of Cu(OAc)₂?H₂O, organic azide and terminal alkyne could oxidatively couple to afford 5‐alkynyl‐1,2,3‐triazole (alkynyltriazole) at room temperature under an atmosphere of O₂ in a few hours. The involvement of 1,5‐diazabicyclo[4.3.0]non‐5‐ene (DBN) is essential, without which the redox neutral coupling instead proceeds to produce 5‐H‐1,2,3‐triazole (protiotriazole) as the major product. Therefore, DBN switches the redox neutral coupling between terminal alkyne and organic azide, the copper‐catalyzed “click” reaction to afford protiotriazole, to an oxidation reaction that results in alkynyltriazole. The organic base DBN is effective in accelerating the copper(II)‐catalyzed oxidation of terminal alkyne or copper(I) acetylide, which is intercepted by an organic azide to produce alkynyltriazole. The proposed mechanistic model suggests that the selectivity between alkynyl‐ and protiotriazole, and other acetylide or triazolide oxidation products is determined by the competition between copper(I)‐catalyzed redox neutral cycloaddition and copper(II)/O₂‐mediated acetylide oxidation after the formation of copper(I) acetylide.     

Light‐Induced Mechanistic Divergence in Gold(I) Catalysis: Revisiting the Reactivity of Diazonium Salts

In a systematic study of the Au‐catalyzed reaction of o‐alkynylphenols with aryldiazonium salts, we find that essentially the same reaction conditions lead to a change in mechanism when a light source is applied. If the reaction is carried out at room temperature using a Au^I catalyst, the diazonium salt undergoes electrophilic deauration of a vinyl Au^I intermediate and provides access to substituted azobenzofurans. If the reaction mixture is irradiated with blue LED light, C?C bond formation due to N₂‐extrusion from the diazonium salt is realized selectively, using the same starting materials without the need for an additional photo(redox) catalyst under aerobic conditions. We report a series of experiments demonstrating that the same vinyl Au^I intermediate is capable of producing the observed products under photolytic and thermal conditions. The finding that a vinyl Au^I complex can directly, without the need for an additional photo(redox) catalyst, result in C?C bond formation under photolytic conditions is contrary to the proposed mechanistic pathways suggested in the literature till date and highlights that the role of oxidation state changes in photoredox catalysis involving Au is thus far only poorly understood and may hold surprises for the future. Computational results indicate that photochemical activation can occur directly from a donor–acceptor complex formed between the vinyl Au^I intermediate and the diazonium salt.     

Simple kinetic method for distinguishing between homogeneous and heterogeneous mechanisms of catalysis,illustrated by the example of “ligand-free” Suzuki and Heck reactions of aryl iodides and aryl bromides

Using a simple method based on an analysis of the phase trajectories of competing reactions of several substrates, it has been established that the selectivity of catalytically active species in the Suzuki reaction of aryl bromides depends on the nature of the catalyst precursor. This indicates that there is a considerable contribution from heterogeneous catalysis. At the same time, in the reaction involving aryl iodides, when the catalyst concentration in the solution is much higher, the selectivity of the catalyst is precursor-independent, suggesting that homogeneous catalysis is dominant. In the Heck reaction of both aryl bromides and aryl iodides, pure homogeneous catalysis takes place.     

Visible‐Light‐Promoted Asymmetric Cross‐Dehydrogenative Coupling of Tertiary Amines to Ketones by Synergistic Multiple Catalysis

Reported herein is an unprecedented photocatalytic asymmetric cross‐dehydrogenative coupling reaction between tertiary amines and simple ketones, and it proceeds by synergistic multiple catalysis with substoichiometric amounts of a hydrogen acceptor. This process is enabled by a simple chiral primary amine catalyst through the coupling of a catalytic enamine intermediate and an iminium cation intermediate in situ generated from tetrahydroisoquinoline derivatives by coupled Ru/Co catalysis.     

聚乙烯负载氮叶立德催化的二氢呋喃衍生物的高选择性合成

利用（O-NX）TiCl3非茂聚烯烃催化剂实现了乙烯和4-(10-十一烯)-吡啶的共聚合反应,成功将吡啶基团负载在聚乙烯上,在5mol%负载的吡啶和1mol%卟啉铁的催化作用下,此聚合物作为负载型催化剂可以高效地催化重氮化合物与双拉电子Michael受体的反应,高产率、高非对映选择性地得到二氢呋喃衍生物. 催化剂至少可以回收3次,反应收率均大于90%. 该催化反应具有分离和纯化方便、催化剂可回收利用、催化剂无挥发性的特点.     

Electron Transfer Chain Catalysis

Electron-transfer chain (ETC) catalysis belongs to the family of chain reactions where the electron is the catalyst. The ETC mechanism could be initiated by chemical activation, electrochemistry, or photolysis. If this pathway is applied to the preparation of organometallic complexes, it utilizes the greatly enhanced reactivity of organometallic 17e and 19e radicals. The chemical propagation is followed by the cross electron-transfer while the electron-transfer step is also followed by the chemical propagation, creating a loop in which reactants are facilely transformed into products. Interestingly the overall reaction is without any net redox change.     

Homogenous redox catalysis competition between electron exchange and proton exchange

Whether proton exchange and nucleophilic substitution reactions can become competitive with electron exchange reactions in homogeneous redox catalysis processes due to the reduction of bromoesters has been evaluated.Electrochemical data have been correlated with the results of the analyses carried out in solution during, and at the end of, the catalytic reduction processes. Thus, it has been possible to obtain the values of γ (γ = c_RX/c_O, where c_RX is the substrate concentration and c_O that of the catalyst corresponding to pure catalysis conditions whereby only the electron-exchange reaction is observed.The hypothesis that the catalyst (9,10-diphenylanthracene) is dihydrogenated by the substrate according to DISP₂ mechanism is in agreement with the experiments.     

Tertiary amine mediated aerobic oxidation of sulfides into sulfoxides by visible-light photoredox catalysis on TiO2

The selective oxidation of sulfides into sulfoxides receives much attention due to industrial and biological applications. However, the realization of this reaction with molecular oxygen at room temperature, which is of importance towards green and sustainable chemistry, remains challenging. Herein, we develop a strategy to achieve the aerobic oxidation of sulfides into sulfoxides by exploring the synergy between a tertiary amine and titanium dioxide via visible-light photoredox catalysis. Specifically, titanium dioxide can interact with triethylamine (TEA) to form a visible-light harvesting surface complex, preluding the ensuing selective redox reaction. Moreover, TEA, whose stability was demonstrated by a turnover number of 32, plays a critical role as a redox mediator by shuttling electrons during the oxidation of sulfide. This work suggests that the addition of a redox mediator is highly functional in establishing visible-light-induced reactions via heterogeneous photoredox catalysis.     

Substrate‐Selective Catalysis

Substrate selectivity is an important output function for the validation of different enzyme models, catalytic cavity compounds, and reaction mechanisms as demonstrated in this review. In contrast to stereo‐, regio‐, and chemoselective catalysis, the field of substrate‐selective catalysis is under‐researched and has to date generated only a few, but important, industrial applications. This review points out the broad spectrum of different reaction types that have been investigated in substrate‐selective catalysis. The present review is the first one covering substrate‐selective catalysis and deals with reactions in which the substrates involved have the same reacting functionality and the catalysts is used in catalytic or in stoichiometric amounts. The review covers real substrate‐selective catalysis, thus only including cases in which substrate‐selective catalysis has been observed in competition between substrates.