光诱导酰基自由基反应的研究进展

近年来,光诱导催化的自由基反应已经成为有机合成化学的研究热点之一.其中,光诱导的酰基自由基化反应是在温和条件下制备酮类化合物行之有效的策略之一.主要综述了光诱导酰基自由基反应的研究进展,介绍了常见酰基自由基的来源及其在有机合成中的应用.     

催化不对称光诱导自由基反应

自由基反应的立体选择性调控一直是不对称催化领域的挑战性难题.近年来,光化学过程特别是可见光化学过程在有机合成中越来越受到研究人员的重视,光诱导自由基化学也再次进入人们的视野.相对传统的自由基化学,光诱导自由基化学反应条件温和,易于调控,为实现高效催化不对称自由基反应带来了新的契机,展示了蓬勃的发展潜力.本文根据光诱导产生自由基种类的不同,简要介绍最近该方向的研究进展.     

草酸酯类化合物在自由基脱羟基化反应中的研究进展

羟基作为醇类化合物的基本结构单元,广泛存在于药物、天然产物、农药以及精细化学品中.烷基自由基则是自由基化学领域最基础性的合成砌块.因此,将醇转化为烷基自由基,具有基础性的研究价值.通常醇类化合物可以通过Barton-McCombie反应,实现自由基形式的脱羟基化反应,得到烷基自由基.然而传统脱羟基化反应存在诸多缺陷.因此发展一种简洁高效的脱羟基化方法具有重要的现实意义.随着近年来有机化学的发展,自由基脱羟基化反应取得突破性进展.本综述节选其中一部分,着重介绍了草酸酯类化合物在自由基脱羟基化反应中的研究进展和设计原理,对比不同活化策略的反应机理,系统性地总结了邻苯二甲酰亚胺类型草酸酯、草酸单酯和草酸酯类化合物在自由基脱羟基化反应中的共性和个性,展望了自由基脱羟基化反应的未来和趋势.     

典型无机含氧酸自由基的特性

碳酸自由基、硝酸自由基、磷酸自由基和硫酸自由基是化学反应的重要中间体，都具有氧化性，对污染物在自然和人为环境中的迁移转化会产生重要的影响.文中较为详细地介绍这几种自由基的电极电位、产生方式、检测方法及与有机物的反应方式.总结四种自由基的特性及与有机物的反应方式可发现，四种自由基和羟自由基电极电位不同，导致它们和有机物反应速率的不同；碳酸自由基并不是羟自由基去除剂，对于一些容易被氧化的化合物，碳酸自由基氧化效果比羟自由基好；四种自由基均可由羟自由基转化而来，并且这四种自由基和羟自由基与有机物反应方式基本一致，都通过电子转移、夺氢和加成的方式进行.可以预测四种自由基和羟自由基降解有机物的机理将非常相似，今后应研究四种自由基与羟自由基相互转化的规律，以及与代表性有机物的反应机理.     

羟基自由基在沸石分子筛合成中的作用

沸石分子筛由于具有独特的形选催化作用及可调的酸性, 已成为化学工业中最重要的固体催化材料. 沸石分子筛的合成主要基于碱性条件下的水热晶化, OH^?被认为起到催化硅铝物种的解聚及聚合作用. 近年来, 研究者发现了羟基自由基加速分子筛的水热晶化机制. 通过利用紫外光照射或芬顿反应等物理或化学方法向分子筛合成体系引入羟基自由基, 可以实现沸石分子筛的加速晶化及高硅沸石分子筛的合成. 理论计算结果表明, 羟基自由基可以促进Si—O—Si 键的断裂和重新生成, 从而显著加快分子筛成核并促进硅原子进入骨架. 本综述介绍了羟基自由基在沸石分子筛晶化方面的最新研究进展, 探讨了羟基自由基的主要作用和优势, 并对沸石分子筛合成的羟基自由基路线发展前景进行了展望.     

以离子液体为溶剂的原子转移自由基聚合

离子液体是一种有机盐,在接近室温下呈液状.离子液体是难挥发、极性高的溶剂,它能溶解很多种有机、无机和金属有机化合物.虽然有越来越多的人报道了有关离子液体在有机合成中的应用,但是在聚合过程中的应用却很少.然而在近几年,科学家证明了离子液体在聚合物的合成中的作用很大.在以离子液体为介质的自由基聚合反应中,kp/kt 会增大.尤其是在原子转移自由基聚合中,以离子液体作为溶剂有助于聚合物与残余催化剂的分离.本文主要阐述了原子转移自由基聚合反应的基本原理、特点以及离子液体在原子转移自由基聚合中的应用,并且还介绍了其他研究者的工作和原子转移自由基聚合的发展前景.     

高分子表面活性剂的合成

介绍了高分子表面活性剂的合成方法及其不同于低分子表面活性剂的特点,重点从离子聚合、活性自由基聚合、缩合聚合、开环聚合、高分子化学反应、自由基胶束聚合等角度综述了近几-来高分子表面活性剂的合成研究进展.     

过硫酸盐促进的自由基反应进展

过硫酸盐作为廉价、环境友好、易操作的强氧化剂,在有机合成中具有广泛的应用.众所周知,过硫酸盐在加热、光照或过渡金属还原条件下可分解产生硫酸根自由基负离子(SO_4~(-g)).研究表明,该自由基负离子具有很强的单电子氧化性,可以氧化各种中性分子或负离子产生相应的自由基活性中间体.这些新生成的活性中间体可以进行一系列化学转化,从而生成结构多样的、有用的化合物.对近几年过硫酸盐促进的自由基反应进行了总结.分五部分:第一、二部分着重阐述过硫酸盐促进的自由基环化以及碳-氢键官能团化反应;第三部分介绍可见光辅助的过硫酸盐促进的有机反应;第四部分简述过硫酸盐促进的其他自由基反应.最后,对过硫酸盐促进的自由基反应进行了总结和展望.     

室温离子液体中的聚合反应

综述了近年来在室温离子液体中聚合反应的研究进展,特别是在配位聚合、自由基聚合、离子聚合及共聚反应,活性自由基聚合,电化学聚合等方面的进展情况;还介绍了离子液体在高分子材料方面的应用情况,展望了离子液体在该领域的应用前景.     

羟基自由基在沸石分子筛合成中的作用（英文）

沸石分子筛由于具有独特的形选催化作用及可调的酸性,已成为化学工业中最重要的固体催化材料.沸石分子筛的合成主要基于碱性条件下的水热晶化, OH-被认为起到催化硅铝物种的解聚及聚合作用.近年来,研究者发现了羟基自由基加速分子筛的水热晶化机制.通过利用紫外光照射或芬顿反应等物理或化学方法向分子筛合成体系引入羟基自由基,可以实现沸石分子筛的加速晶化及高硅沸石分子筛的合成.理论计算结果表明,羟基自由基可以促进Si—O—Si键的断裂和重新生成,从而显著加快分子筛成核并促进硅原子进入骨架.本综述介绍了羟基自由基在沸石分子筛晶化方面的最新研究进展,探讨了羟基自由基的主要作用和优势,并对沸石分子筛合成的羟基自由基路线发展前景进行了展望.     

Time-resolved FT-EPR study of photoreduction of duroquinone by triethylamine in methanol

Using time resolved Fourier transform EPR spectroscopy the photoreduction of duroquinone by triethylamine in methanol solution was investigated. It is found that the spin-polarized (CIDEP) duroquinone triplet deactivates by electron transfer from triethylamine generating duroquinone radical anion and amine radical cation, and by hydrogen transfer from the solvent generating durosemiquinone radical and hydroxymethyl radical, respectively. All radicals are observed at different conditions and are spin-polarized by triplet mechanism and partially by ST₀ radical pair mechanism. The time dependence of FT-EPR intensities of radical cation and radical anion on the amine concentration is investigated in the range of 1 to 100 mM triethylamine. The contribution of the triplet mechanism to the spin polarization of radicals changes with different triethylamine concentrations. The durosemiquinone radical is found to be transformed into duroquinone radical anion in the presence of triethylamine in the solution. CIDNP experiments indicate that the hydrogen back transfer between the durosemiquinone radical and hydroxymethyl radical pair has a significant influence on the time behaviour of duroquinone radical anion. The intensity of triethylamine radical cation is found to be decreased with the increase of triethylamine concentration, which is interpreted that the triethylamine radical cation is deprotonated by the amine. Based on the FT-EPR results, a new complete mechanism is proposed.     

Ionizing radiation induced reactions of 2,6-dichloroaniline in dilute aqueous solution

In pulse radiolysis investigations the hydroxyl radical formed in water radiolysis reacts with 2,6-dichloroaniline in radical addition to the ring forming hydroxy-cyclohexadienyl radical and also in hydrogen atom abstraction from the amino group resulting in anilino radical. The hydroxy-cyclohexadienyl radical in the absence of dissolved O₂ partly transforms to anilino radical, when dissolved oxygen is present the radical transforms to peroxy radical. According to chemical oxygen demand measurements the reaction of one OH radical induces the incorporation of 0.6 O₂ into the products. It is a typical value for chlorine atom substituted aromatic molecules, and smaller than found for molecules without chlorine atom (1.0–2.0).     

Generation and absolute reactivity of an aryl enol radical cation in solution

Laser flash photolysis of 1-bromo-1-(4-methoxyphenyl)acetone in acetonitrile leads to the formation of the alpha-acyl 4-methoxybenzyl radical that under acidic conditions rapidly protonates to give detectable amounts of the radical cation of the enol of 4-methoxyphenylacetone. This enol radical cation is relatively long-lived in acidic acetonitrile (tau approximately equal to 200 micros), which is on the same order of magnitude as the radical cations of other 4-methoxystyrene derivatives. Rate constants for deprotonation of the radical cation and the acid dissociation constant for the enol radical cation were also determined using time-resolved absorption spectroscopy. Deprotonation is rapid, taking place with a rate constant of 3.9 x 10(6) s(-1), but the enol radical cation is found to be only moderately acidic in acetonitrile having a pK(a) = 3.2. The lifetime of the enol radical cation was also found to be sensitive to the presence of oxygen and chloride. The sensitivity toward oxygen is explained by oxygen trapping the vinyloxy radical component of the enol radical cation/vinyloxy equilibrium, while chloride acts as a nucleophile to trap the enol radical cation.     

LIGHT-INDUCED ELECTRON TRANSFER REACTIONS BETWEEN CHLOROPHYLL AND QUINONE IN LIPOSOMES: RADICAL FORMATION AND DECAY IN NEGATIVELY AND POSITIVELY CHARGED VESICLES*

Abstract— The incorporation of relatively small amounts (≤ 20 mol%) of a negatively charged surfactant into otherwise electrically neutral phosphatidylcholine vesicles containing chlorophyll in the presence of benzoquinone has been shown to produce large effects on radical formation and decay as measured by laser flash photolysis. When salt ions are present in the aqueous phase, increasing the level of negative surfactant leads to a small increase in radical yield, followed by a larger decrease in radical yield. When the salt concentration is low, increasing the negative surfactant concentration leads to a suppression of the fast radical recombination process, an increase in slow radical decay and, at the highest surfactant concentration, an approximately 35% increase in total radical yield. An analysis of these effects is given in terms of the influence of a negative electrostatic field on radical pair stabilization and recombination, radical pair separation and expulsion of the acceptor radical anion from the vesicle. The incorporation of relatively small amounts (≤ 20 mol%) of a positively charged surfactant into egg phosphatidylcholine (EPC) vesicles containing chlorophyll and benzoquinone also produces large effects on radical formation and decay. When the electrolyte concentration in the suspending aqueous medium is high, radical yields are decreased as the surfactant concentration is increased, without any appreciable effect on decay kinetics. When deionized water is used, the slow recombination component of the decay is specifically suppressed by the presence of the positive surfactant, whereas the fast decay component decreased and then increased in amount as the surfactant concentration is increased. In all cases, however, the total radical yield is less than in pure EPC vesicles. These results can be understood in terms of the influence of a positive electrostatic field on radical pair separation and acceptor radical anion mobility. When equimolar amounts of both positively and negatively charged surfactants are incorporated into EPC vesicles, the radical yields and decay kinetics are relatively unaffected, but a large effect is observed on the radical difference spectrum. This may be a consequence of clustering of oppositely charged molecules within the bilayer surface.     

分子间自由基正离子反应研究进展

自由基正离子含有一个正电荷和一对未成对电子,是很多有机化学反应的重要的活性中间体。文章综述了近几年自由基正离子反应研究进展,主要包括化学氧化剂诱导的自由基正离子反应、可见光诱导的自由基正离子反应、电诱导的自由基正离子反应等方面的研究。     

SPIN TRAPPING OF FREE RADICALS PRODUCED FROM NITROSOAMINE CARCINOGENS

Abstract— Using the spin trap 5,5-dimethylpyrroline-1-oxide we have demonstrated that the nitrosoamine carcinogen, 1-nitrosopiperidine, upon incubation with rat liver microsomes and nuclei produces two trapped free radical species. One trapped species is the hydroxyl free radical whereas the other is a free radical of unknown structure of the carcinogen itself. Three other nitrosoamine carcinogens tested, including diethylnitrosoamine, dimethylnitrosoamine and 1-nitrosopyrroline yielded similar results with the exception that the trapped carcinogen radical differs dependent upon the compound used. Oxygen was required to produce the hydroxyl free radical but its presence decreased the yield of the carcinogen radical. Both cyanide and α-tocopherol acetate caused a decrease in the yield of the carcinogen free radical. Some heat-labile inhibitor(s) of radical production was/were present in the cytosol. The amount of radical produced was not proportional to the P₄₅₀ content.     

Theoretical study of ribonucleotide reductase mechanism-based inhibition by 2'-azido-2'-deoxyribonucleoside 5'-diphosphates

2'-azido-2'-deoxyribonucleoside 5'-diphosphates are mechanism-based inhibitors of Ribonucleotide Reductase. Considerable effort has been made to elucidate their mechanism of inhibition, which is still controversial and not fully understood. Previous studies have detected the formation of a radical intermediate when the inhibitors interact with the enzyme, and several authors have proposed possible structures for this radical. We have conducted a theoretical study of the possible reactions involved, which allowed us to identify the structure of the new radical among the several proposals. A new reactional path is also proposed that is the most kinetically favored to yield this radical and ultimately inactivate the enzyme. The energetic involved in this mechanism, both for radical formation and radical decay, as well as the calculated Hyperfine Coupling Constants for the radical intermediate, are in agreement with the correspondent experimental values. This mechanistic alternative is fully coherent with remaining experimental data.     

Reprint of: Recent advances in the functionalization of allenes via radical process

This review is focused on the recent advances in the functionalization of allenes via radical process. Different radical partners including carbon radicals and heteroatom radicals are discussed in the reactions of allenes. Generally, the radical formed in situ would attack the allene at the central carbon leading to allyl radical intermediate. However, the formation of alkenyl radical intermediate from allene could be observed as well in some cases with high regioselectivity and stereoselectivity.     

Recent advances in the functionalization of allenes via radical process

This review is focused on the recent advances in the functionalization of allenes via radical process. Different radical partners including carbon radicals and heteroatom radicals are discussed in the reactions of allenes. Generally, the radical formed in situ would attack the allene at the central carbon leading to allyl radical intermediate. However, the formation of alkenyl radical intermediate from allene could be observed as well in some cases with high regioselectivity and stereoselectivity.     

Regiodivergent C−H Acylation of Arenes by Switching from Ionic- to Radical-Type Chemistry Using NHC Catalysis

The Friedel–Crafts acylation reaction, which belongs to the class of electrophilic aromatic substitutions is a highly valuable and versatile reaction in synthesis. Regioselectivity is predictable and determined by electronic as well as steric factors of the (hetero)arene substrate. Herein, a radical approach for the acylation of arenes and heteroarenes is presented. C−H acylation is achieved through mild cooperative photoredox/NHC radical catalysis with the cross-coupling of an arene radical cation with an NHC-bound ketyl radical as a key step. As compared to the classical Friedel–Crafts acylation, a regiodivergent outcome is observed upon switching from the ionic to the radical mode. In these divergent reactions, aroyl fluorides act as the acylation reagents in both the ionic as well as the radical process.