安息香及其衍生物光反应的CIDNP研究

本文用光照的¹H化学诱导动态核极化技术,研究了安息香及其衍生物的光化反应。并通过不同浓度的自由基捕获剂(PBN)的加入,对所研究体系的CIDNP效应的影响,分析推断了安息香等的光解及其光解自由基的复合的反应机理。并讨论了双取代安息香醚的光反应机理随取代基的变化而有所不同。     

化学诱导动态核极化

简要概述了化学诱导动态核极化(CIDNP)的发展历史、原理及在自由基反应机理研究方面的应用。     

多相氧载体CoO-MgO和氧分子作用的ESR研究

用ESK研究多相氧载体CoO-MgO表面上氧的吸附作用,发现在77-150K温度范围内表面Co²⁺离子和O₂的结合是可逆的,吸附产生Co³⁺-O₂^-自由基加合物有超精细结构的ESR谱;当温度增加,吸附态O₂^-自由基发生转移并稳定在Mg²⁺离子上形成Mg²⁺-O₂^-自由基,文中着重讨论Co³⁺-O₂^-自由基的电子结构和成键本质,认为自由基是通过自旋成对的方式形成的,由于σ-л键作用引起的自旋极化以及由于电子离域作用而引起的偶极作用与ESR制的超精细结构线产生有关。     

吩噻嗪-1,4萘醌-乙二醇体系光化学过程的时间分辨ESR研究

用时间分辨ESR方法研究了吩噻嗪(PTH)-1,4-萘醌(NQ)-乙二醇(RH)体系中的光化学过程.只观察到萘醌的中性半醌自由基NQH^*的全发射极化的CIDEP(化学诱导动态极化)信号,并未观察到极化的萘醌负离子NQ·^-*的CIDEP信号,表明RH与三重态NQ间的质子转移反应远比PTH与NQ间的电子转移反应为快.NQH·^*的CIDEP信号随pH值的变化表明体系中同时有极化自由基NQH·^*与NQH·₂^+*存在,并且其间有质子交换.     

基于散射实验极化靶的2.5T/1.3K的动态核极化(DNP)系统的开发

动态核极化法(Dynamic Nuclear Polarization,DNP)是利用热平衡下的电子在磁场中的高自旋极化率转移到原子核自旋的技术,从而极大的提高原子核自旋极化率.多种动态极化靶材料已广泛的用于自旋物理散射实验.本文介绍一种简单实用,共同开发的日本山形大学DNP系统,包括超导磁场,氦4蒸发恒冷器,微波系统以及NMR核磁共振检测系统,测得中子靶材料氘带丁醇(D-butanol)中氘核的极化率在2.5 T/1.3 K达到+6.5%.     

基于散射实验极化靶的2.5T/1.3K的动态核极化(DNP)系统的开发

动态核极化法(Dynamic Nuclear Polarization, DNP)是利用热平衡下的电子在磁场中的高自旋极化率转移到原子核自旋的技术,从而极大的提高原子核自旋极化率。多种动态极化靶材料已广泛的用于自旋物理散射实验。本文介绍一种简单实用,共同开发的日本山形大学DNP系统,包括超导磁场,氦4蒸发恒冷器,微波系统以及NMR核磁共振检测系统,测得中子靶材料氘带丁醇(D-butanol)中氘核的极化率在2.5T/1.3K达到+6.5%。     

激光引发自由基反应磁效应的光谱学研究

“动态自旋化学”(dynamic spin chemistry)作为一门新兴的交叉研究领域,其重要性已得到广泛的共识。涉及的研究内容包括： 化学反应的磁效应(MFE)、同位素效应(MIE)、化学诱导动态核极化(CIDNP)和化学诱导动态电子极化(CIDEP)。文章简要介绍了激光引发自由基反应的磁效应发展历史及其光谱学研究方法。分析并总结了自由基反应磁效应产生的原因、单-三转换理论及磁效应机理。同时,也为国内同行介绍了自由基反应磁效应研究新的发展动态。     

TX-100胶束中光解蒽醌的TR-ESR研究

用时间分辨电子自旋共振(TRESR)波谱仪研究了光解蒽醌自由基的化学诱导动态电子极化(CIDEP).实验测量表明,在蒽醌/乙二醇/TX-100体系中,蒽半醌自由基AQH·有很强极化ESR信号,在激光激发后~0.8μs,检测到蒽醌负离子基AQ·^-的信号,表明AQH·自由基部分地离解为负离子基AQ·^-.     

安息香激光光解的CIDNP研究

采用Nd/YAG激光器的三倍频激光脉冲(355nm),研究了安息香的激光光解过程及其CIDNP效应,获得了不同动力学参数d₉下的CIDNP谱,由此对预测的反应机理作出了证实.通过自编程序,根据对两种光反应产物不同形成途径的CIDNP模拟谱的计算,对安息香光解过程CIDNP效应芳环上质子的极化情况作出了合理归属.     

光解杜醌/氢给体均相体系的CIDEP研究

以杜醌为光敏剂,用高时间分辨电子自旋共振 (TRESR)波谱仪研究了杜醌/乙二醇体系、杜醌/氮氧自由基/乙二醇体系的化学诱导动态电子自旋极化(CIDEP).实验表明,紫外激光照射下,在杜醌/乙二醇溶液中得到以三重态机理极化为主的中性杜半醌自由基DQH*和以碳为中心的乙二醇碳自由基R*(OH)2的极化信号,而加入氮氧自由基 TEMPO后,则只观测到极化的TEMPO的E+E/A极化谱,其产生机理属于以四重态为先驱的自由基-三重态对极化机理(QP-RTPM),结合极化强度的理论计算对该体系的极化形成过程进行了分析.     

The CIDNP effect in plastic crystals

The CIDNP effects in the photolysis reactions of some aldehydes and ketones (including linear, aromatic and cyclic) in plastic crystals of cyclohexane have been discovered and studied. In going from liquid to solid solutions, the change of polarization sign is observed for some substances investigated. The CIDNP effect for a simple model for a relative motion of atoms of radicals possessing spin density (translational diffusion in a restricted volume) has been calculated. The results observed are interpreted in the framework of the radical pair mechanism of CIDNP effect formation.     

Chemically amplified 19F-1H nuclear Overhauser effects

Chemically induced dynamic nuclear polarisation (CIDNP) is explored as a source of nuclear hyperpolarisation in heteronuclear Overhauser effect experiments. A photochemical reaction proceeding through a radical pair intermediate is used to enhance (19)F nuclear magnetisation in 3-fluorotyrosine by more than an order of magnitude with a corresponding increase in the amplitudes of (19)F-(1)H cross-relaxation and cross-correlation effects. The reactions employed are cyclic and leave the sample chemically unchanged. The potential for enhancing the sensitivity of heteronuclear NOEs in (19)F-labelled proteins is discussed.     

Time resolved CIDNP study of electron transfer reactions in proteins and model compounds

Intramolecular electron transfer (IET) from tyrosine to tryptophan cation radicals is investigated using time resolved chemically induced dynamic nuclear polarization (CIDNP) spectroscopy in combination with laser flash photolysis. In both the tryptophan-tyrosine dipeptide and the denatured state of hen lysozyme in aqueous solution, the transformation TrpH⁺ → TyrO by IET leads to an increase in the tyrosine radical concentration, growth in the tyrosine CIDNP signal, fast decay of the tryptophan CIDNP, and inversion of the phase of the CIDNP of the photosensitizing dye, 2,2′-dipyridyl. IET effects are not observed for mixtures of the amino acid or for the native state of lysozyme. The steady state CIDNP effects seen for denatured lysozyme thus depend not only on the accessibility of the amino acid residues on the surface of the protein but also on the reactivity of the radical intermediates.     

The CIDNP kinetics in recombination of successive radical pairs

A theory of chemically induced dynamic nuclear polarization (CIDNP) formed in recombination of successive radical pairs (PRs) is developed. The theory is based on that of RP recombination with the spin Hamiltonian instantaneously changing in time. With kinematics approximation it is shown that general relations for CIDNP are fully expressed via the quadratures of Green functions, which characterize the molecular motion of reagents. Analytical formulae for the time dependence of CIDNP both of primary and secondary RPs have been derived in the strong magnetic field approximation (S-T₀ approximation); field dependences of stationary CIDNP effect for some model cases have been analyzed. For long-lived systems the sensitivity of secondary RP CIDNP to the singlet-triplet evolution of primary RP has been demonstrated. It is shown that sometimes the correct analysis of the effect calls for taking into account the reactivity anisotropy.     

Coherent Polarization Transfer Effects Are Crucial for Interpreting Low-Field CIDNP Data

In this work we demonstrate that low-field chemically induced dynamic nuclear polarization (CIDNP) is strongly affected by re-distribution of polarization, which is formed in the course of spin evolution in transient radical pairs, in diamagnetic reaction products. This phenomenon is of importance when the spins of the reaction product are coupled strongly meaning that spin–spin interactions between them are comparable to the differences in their Zeeman interactions with the external magnetic field. In this case, polarization transfer relies on a coherent mechanism; as a consequence, spins can acquire significant polarization even when they have no hyperfine coupling to the electron spins in the radical pairs, i.e., cannot be polarized directly by CIDNP. This is demonstrated by taking CIDNP of n-butylamine as an example: in this case only the α-CH₂ protons are polarized directly, which is confirmed by high-field CIDNP, whereas the β-CH₂, γ-CH₂ and δ-CH₃ protons get polarized only indirectly due to the transfer of polarization from the α-CH₂ protons. These results show that low-field CIDNP data should be interpreted with care to discriminate between the effects of spin evolution in transient radical pairs and in diamagnetic reaction products.     

Photooxidation of Histidine by 3,3′,4,4′-Benzophenone Tetracarboxylic Acid in Aqueous Solution: Time-Resolved and Field-Dependent CIDNP Study

The photooxidation reaction between 3,3′,4,4′-benzophenone tetracarboxylic acid (TCBP) and l-histidine (His) has been investigated in neutral aqueous solution using the technique of chemically induced dynamic nuclear polarization (CIDNP). Relative values of ¹³C isotropic hyperfine couplings in the TCBP and His radicals were obtained from the ¹³C-time-resolved CIDNP spectrum, recorded during the photoreaction of TCBP with His at natural abundance of the magnetic isotope ¹³C. Good agreement was found for the hyperfine coupling constants of the TCBP ketyl radical calculated using methods of density functional theory, and those obtained from the ¹³C-time-resolved CIDNP spectrum. The mechanism of the quenching reaction of triplet-excited TCBP by His in neutral aqueous solution was established. ¹H CIDNP field dependencies for the photoreaction of TCBP with His were obtained and the g-factor of the histidyl radical was found.     

双环戊二烯-氯醌体系的CIDNP研究

利用Nd/YAG激光器的三倍频激光脉冲(355nm),对双环戊二烯的光敏化反应进行了CIDNP方面的研究,结合CIDNP理论模拟谱的计算,证实了Roth等人所推测的此光敏化反应自由基中间体结构为双重的烯丙基物种,通过计算,确定了自由基各质子的超精细偶合常数hfc的相对大小和绝对符号以及各碳原子上的未偶电子自旋密度,从而对这个特殊的自由基中间体结构有了更清晰的认识.     

A Chemically Induced Magnetic Polarization Study of the Photoreduction of Tetrachloro-p-Benzoquinone

The potential applications of chemically induced dynamic magnetic polarization in photochemistry have recently been emphasized^1. The better understanding of the mechanisms involved in the magnetic polarization permits the combination of CIDEP, CIDNP, and the conventional e.s.r. and n.m.r. techniques to be a powerful tool with which to study organic photochemistry involving excited triplet states and free radical reactions. The recent discovery of electron polarization in photosynthesis systems² is expected to open another exciting area for magnetic polarization applications. The photolysis of tetrachloro-p-benzoquinone, p-Chloranil, has attracted much attention^3,4 as model system in conventional e.s.r. studies. We report here a further investigation of the photoreduction of p-chloranil by a variety of hydrogen donors using the combined e.s.r., CIDEP and CIDNP method.     

Influence of nitroxides on CIDNP of micellised radical pairs and short-lived biradicals

The effects of stable nitroxide radicals on stimulated nuclear polarization (SNP) and chemically induced dynamic nuclear polarization (CIDNP) in short-lived consecutive biradicals and radical pairs in homogeneous solutions as well as spin-correlated radical pairs in micelles were studied in high and low magnetic fields. It is shown that experimentally observed effects of nitroxide additions on CIDNP and SNP can be well simulated taking into account only the increase in the rates of relaxation in the paramagnetic species constituting radical pairs or biradicals. Effects of coherent spin evolution in three-spin systems under study seem to be of negligible importance.