氧/硫杂卟啉内氢迁移反应的理论研究

采用B3LYP/6-31G**方法在Gaussian 03程序下, 对氧杂卟啉(OPH), 硫杂卟啉(SPH)的结构和能量进行优化, 并寻找与内氢迁移反应相关的过渡态构型. 计算结果表明, 由于分子内氢键的存在, 氧或硫杂化均会使卟吩内氢迁移正负反应速率明显降低.     

卟啉内氢迁移反应氟取代基效应的理论研究

The structures and energies of reactant, product, intermediate, transition and second order saddlepoint in the transfer reaction of inner hydrogen atoms in porphine(PH2), m-tetra-fluorine porphyrin(m-TFPH2), β-octa-fluorine-porphyrin (β-OFPH2) and m-tetra-fluorine, β-octa-fluorine-porphyrin(12FPH2) were calculated by using B3LYP/6-31G** method under certain symmetry restriction. In the transfer reaction of inner hydrogen atoms in all various matters, the comparison of structures and the energies shows that the probabilities of asynchronous mechanism are larger than that of synchronous mechanism via a second-order saddle-point, and substitutents to porphyrin in hydrogen migration have no influence on mechanism choice. But the substitutents can affect speed differences between the synchronous mechanisms and the asynchronous mechanisms. In addition, fluoro substitutents decrease speeds of positive and negative reactions in asynchronous mechanisms, which is in agreement with chemical intuition.     

卟吩内氢迁移反应的理论研究

用B3LYP/6-31G~(* *)方法计算卟吩内氢迁移反应中的反应物、产物、中间体 、过渡态及其二级鞍点的结构与能量、结果表明，分步反应历程的几率较大，与实 验的预测一致，同时对几种理论研究的结果进行了分析比较。     

四苯基卟啉质子化结构变化的理论研究

用半经验的ＡＭＩ ＭＯ方法,进行合理的对称性限制,计算了一类重要的卟啉衍生物──四苯基卟啉（ＴＰＰＨ_２）及其质子化二酸（ＴＰＰＨ_4~2 ）的构型,并通过结构分析,电荷布居分析和前线轨道分析,讨论了质子化过程中的构型变化以及这种变化对分子堆积可能带来的影响。     

四吡啶基卟啉质子化结构变化的理论研究

为考察m-吡啶基对质子化卟啉结构的影响,用半经验的AM1MO方法,并进行合理的对称性限制,计算了一类重要的卟啉衍生物---四吡啶基卟啉(TPyPH~2)及其质子化二酸(TP~yPH~4^2^+)的构型。通过结构分析,电荷布居分析和前沿轨道分析,讨论了质子化过程中的构型变化以及这种变化对分子堆积可能带来的影响。     

烯基自由基参与的分子内氢原子转移反应的新进展

近年来烯基自由基引发的氢原子转移反应受到了广泛的关注.利用该策略可以实现自由基成环反应和区域选择性的远程sp3碳氢键官能化反应,包括碳氢键烯基化、炔基化、卤化及芳基化等反应.在该类反应中,烯基自由基的产生方式由传统的烯基卤化物单电子还原,拓展到通过外加自由基对炔基的加成.这些反应依据底物类型的不同,机理路径也有所不同....     

几种常见氢迁移反应的理论新见解

氢迁移反应是常见的有机反应,氢迁移反应历程有不同的类型。通常认为大部分氢迁移反应发生在分子内。我们对几种典型氢迁移反应的研究结果发现,这些反应的分子间氢迁移明显比分子内氢迁移在能量上更占优势。     

四苯基卟啉质子化结构变化的理论研究（Ⅱ）－－五氟苯基及吡咯环上氟的取代基效应

卟啉的衍生物在DNA螺旋中的嵌入并堆积具有高选择性。为考察5，10，15，20－四（五氟苯基）卟啉（TF5PPH2）和2，3，7，8，12，13，17，18－八氟－5，10，15，20－四（五氟苯基）卟啉（F28TPPH2）中F取代基对质子化卟啉结构的影响，在四苯基卟啉研究的基础上，用半经验的AM1 MO方法，并进行合理的对称性限制，计算了TF5PPH2和F28TPPH2及其质子化二酸（TF5PHH4^2 ）和（F28TPPH4^2＋）的几种可能的构型。结果表明，由于F取代基的影响，质子化过程中的结构、键电荷布居和前线分子轨道均有明显的变化，二者的质子化二酸与溶液质子的快速交换作用也都变得更加困难。     

紫外-可见分光光度法测定溴代卟啉的质子化反应常数

采用紫外-可见分光光度法研究了溴代卟啉(H2TPPBrx)在N,N-二甲基甲酰胺(DMF)中的吸收光谱性质,并测定了其在非水溶剂DMF中与HClO4反应的质子化常数。结果表明H2TPP,H2TPPBr2在DMF溶剂中与高氯酸反应得到两个质子生成[H4TPP]2 和[H4TPPBrx]2 ,而H2TPPBr3,H2TPPBr4只能得到一个质子生成[H4TPPBrx] 和[H4TPPBrx] ,其质子化常数分别为:lgK1=3.28,lgK2=2.86,lgK3=2.16,lgK4=1.93。     

甲硫醇和氢原子反应的从头算直接动力学

利用双水平直接动力学方法对反应CH3SH+H的微观机理和动力学性质进行了理论研究.对于此反应的三个反应通道,即—SH和—CH3基团上的两个氢提取通道及一个取代通道,在MP2/6-311+G(d,p)水平上优化得到了各稳定点的结构及振动频率,并在G3(MP2)水平上进行了单点能量计算以获得更精确的能量信息;在此基础上运用结合小曲率隧道效应校正的变分过渡态理论(CVT/SCT)计算了各反应通道在220-1000 K温度区间的速率常数.计算结果表明提取—SH基团上H的反应通道R1在整个反应温度区间都是主要通道,而随着温度的升高,低温下的次要反应通道——取代通道R3变得越来越重要,并且在高温下将成为一个竞争的反应通道;提取—CH3基团上H的反应通道(R2)由于具有较高的反应能垒,因而,其对总反应速率常数的贡献可以忽略.计算得到的总反应速率常数与已有的实验值符合得很好,进而我们预测了该反应在220-1000 K温度范围内速率常数的表达式为:k=5.00×10-18T2.39exp(-119.81/T),为将来的实验研究提供参考.     

SOMOphilic Alkynylation of Unreactive Alkenes Enabled by Iron-Catalyzed Hydrogen Atom Transfer

We report an efficient and practical iron-catalyzed hydrogen atom transfer protocol for assembling acetylenic motifs into functional alkenes. Diversities of internal alkynes could be obtained from readily available alkenes and acetylenic sulfones with excellent Markovnikov selectivity. An iron hydride hydrogen atom transfer catalytic cycle was described to clarify the mechanism of this reaction.     

亚胺自由基引发的1，5-氢原子转移反应研究进展

通过亚胺自由基引发的1,5-氢原子转移（Hydrogen Atom Transfer,HAT）途径实现C(sp³)−H键官能团化,可避免导向基团和当量氧化剂的使用,因而引起了研究人员的广泛关注。近年来,过渡金属和可见光氧化还原体系的发展为高效可控产生亚胺自由基提供了可靠的方法。本文根据亚胺自由基的来源分类总结了亚胺自由基引发的1,5-氢原子转移实现C(sp³)−H键官能团化反应。     

Catalytic Hydrogen Atom Transfer (HAT) for Sustainable and Diastereoselective Radical Reduction

Going cyclic! A catalytic cycle and cyclic transition states enable a novel sustainable and catalytic hydrogen atom transfer (HAT) for highly diastereoselective radical reductions. Readily available nontoxic silanes are the terminal reductants for epoxides that are opened by bifunctional titanocene(III) hydride catalysts.     

Theoretical Study on the Excited-state Intramolecular Hydrogen Abstraction Reactions of Butanal

The excited-state intramolecular hydrogen abstraction reactions of butanal have been investigated using the CAS-MP2/6-311＋G^＊//CASSCF/6-31G^＊ methods. Calculated results show that the hydrogen transfer induced fluorescence quenching of the n,π^＊-excited state of covalent butanal with three paths： （1） The first path corresponds to direct S0-react reconstitution, which involves the first S1 decay by partial hydrogen atom transfer. （2） The second stepwise mechanism can be viewed as a full hydrogen atom transfer followed by a partial hydrogen atom back transfer, electron transfer （near S1/S0 or S0-TS） and finally a proton transfer to S0-react. （3） On the triplet surface, the surface crossing to the singlet state would be clearly much efficient at the T1/S0 region due to the large SOC value of 8.3 cm^-1. The S0-react decay route from T1/S0 was studied with an intrinsic reaction coordinate （IRC） calculation at the CASSCF level, resulting in the S0-React minimum.     

Switchover of the Mechanism between Electron Transfer and Hydrogen‐Atom Transfer for a Protonated Manganese(IV)–Oxo Complex by Changing Only the Reaction Temperature

Hydroxylation of mesitylene by a nonheme manganese(IV)–oxo complex, [(N4Py)Mn^IV(O)]²⁺ ( 1 ), proceeds via one‐step hydrogen‐atom transfer (HAT) with a large deuterium kinetic isotope effect (KIE) of 3.2(3) at 293 K. In contrast, the same reaction with a triflic acid‐bound manganese(IV)‐oxo complex, [(N4Py)Mn^IV(O)]²⁺‐(HOTf)₂ ( 2 ), proceeds via electron transfer (ET) with no KIE at 293 K. Interestingly, when the reaction temperature is lowered to less than 263 K in the reaction of 2 , however, the mechanism changes again from ET to HAT with a large KIE of 2.9(3). Such a switchover of the reaction mechanism from ET to HAT is shown to occur by changing only temperature in the boundary region between ET and HAT pathways when the driving force of ET from toluene derivatives to 2 is around ?0.5 eV. The present results provide a valuable and general guide to predict a switchover of the reaction mechanism from ET to the others, including HAT.     

8-羟基喹啉单体及二聚体质子转移反应的理论研究

Density functional theory （DFT） of quantum chemistry method was employed to investigate proton transfer reactions of 8-hydroxyquinoline （8-HQ） monomers and dimers. By studying the potential energy curves of the isomerization, the most possible reaction pathway was found. The total energy of 8-hydroxyquinoline was lower than that of quinolin-8（1H）-one, whereas the order was reversed in dimers. The findings explained the contrary experimental phenomena. The minimum reaction barrier of intramolecular proton transfer was 47.3 kJ/mol while that in dimer was only 25.7 kJ/mol. Hence it is obvious that proton transfer reactions of 8-HQ monomer have a considerable rate but it is easier to proceed for 8-HQ dimer than monomers. It implied that the hydrogen bond played an important role in depressing the activation energy of reaction. The mechanism of the tautomerization was discussed on the basis of theoretical results.