乙基曙红碘翁盐的染料再生循环光敏体系

本文设计了染料循环再生的光敏反应体系, 通过对占吨碘翁盐电子反应机制的深入研究, 提出了占吨染料在光敏反应过程中的染料再生循环, 它依次由三个反应过程组成: 在光作用下, 通过电子转移反应, 产生染料氧化褪色体(I); 在H给体存在下, 通过H转移反应, 使产物(I)转化为染料酸式隐色体(II); 在碱作用下, (II)发生去质子反应, 染料再生回复到染料的起始结构。其中光、H给体和碱的作用是再生循环的三个要素, 而控制染料酸式隐色体生成比例是染料再生效率的关键。由乙基曙红碘翁盐/三乙胺组成的染料再生体系的染料敏化效率比单一体系高4倍左右, 同时使活性自由基的数量增殖, 这种体系在实际应用方面具有重要意义。     

可见光敏引发体系荧光黄双二苯基碘钅翁盐的研究

通过计算呫吨染料与二苯基碘钅翁盐反应的电子转移参数, 发现荧光黄与二苯基碘钅翁盐反应的热力学驱动力最大, 证明了实现光敏化方式是电子转移反应. 通过对引发体系吸收光谱的研究, 考察了不同价键结构、溶剂效应及引发剂浓度对引发体系吸收光谱的影响, 证实了与C-6位酚氧离子相结合的离子种类很大程度上决定了染料敏化体系的吸收峰强度及峰形状, 溶剂极性增大, 吸收光谱红移; 溶剂极性减小, 其吸收光谱蓝移. 在非极性溶剂中, 引发剂浓度越高, 其解离度越大, 引发剂更多地以自由离子形式存在.     

荧烷染料／二芳基磺Weng盐同步光生色和光聚合体系

荧烷染料和二芳基碘Ｗｅｎｇ盐组成的体系，在光作用下，通过激发态的荧烷染料与碘Ｗｅｎｇ之间发生电子转移反应，生成开环结构的荧烷染料有色体，伴随发生Ｗｅｎｇ盐的光解反应，生成活性引发自由基碎片。该体系不仅可有效地引发烯类单体的聚合反应，也可同步发生光生色作用，产生较高的色密度。     

荧烷染料的光诱导显色反应和机制的研究

荧烷染料是一类重要的功能性染料,广泛地应用于热敏和压敏记录材料.通常采用在酸作用下,使荧烷染料发生显色反应,由内酯环结构的无色体生成开环结构的有色体.并且通过吨环上不同取代基得到各种色调.荧烷染料有色体不稳定,在一般有机介质中容易发生褪色反应,使得荧烷染料作为记录介质普遍存在着色稳定性差、保存期短的缺点.为了改善有色体的稳定性,人们进行了大量的工作^[1-3],但均未取得重要进展.考虑到荧烷染料母核上带有烷胺基取代基,具有电子给体特性,有可能通过电子转移反应的途径进行显色反应.实现这种电子转移显色过程的关键问题是选择合适的电子受体.为此采用盐类化合物如碘盐和硫盐作为电了受体,因为它们容易和不同电子给体组成电子转移光敏反应体系^[4-6].因此,本文研究了以荧烷染料为电子给体和碘盐为电子受体的光致电子转移显色反应,并提出了显色反应机制.     

光氧化还原碘盐引发阳离子固化的研究

合成了二苯基碘六氟磷酸盐光引发剂。研究了染料的种类和浓度对碘盐引发阳离子光固化速度的影响，用光致电子转移（光氧化还原）理论解释了这些光敏染料的光敏机理。     

光氧化还原碘Wong盐引发阳离子固化的研究

合成了二苯基碘Ｗｏｎｇ六氟磷酸盐光引发剂。研究了染料的种类和学地磺Ｗｏｎｇ盐引发阳离子光固化速度的影响，用光致电子转移理论解释了这些光敏染料的光敏机理。     

染料敏化太阳能电池中二聚噻吩类光敏染料构效关系的理论研究

D-π-A型有机光敏染料结构上的微小差异会引起器件性能的显著不同. 为了合理解释染料分子1和2(给体分别为咔唑和二氢吲哚)结构与性能之间的关系, 采用密度泛函理论(DFT)和含时密度泛函理论(TD-DFT)讨论了包括紫外-可见吸收光谱、 光捕获效率、 电子注入驱动力、 垂直方向偶极矩和电子转移数目在内的一系列影响染料性能的理论参数. 结果表明, 在光捕获效率和电子注入效率差别不大的情况下, 染料分子2较低的染料再生效率可导致其短路电流较小; 同时, 在由光诱导产生的从染料分子转移到半导体的电子数目以及电子复合程度相差不大的情况下, 染料分子1垂直方向上较大的偶极矩则可导致其具有较高的开路电压. 计算结果与实验值相吻合, 有望对今后设计合成高效光敏染料提供一定的理论指导.     

曙红染料-碘鎓盐复合体系的光化学性质和引发丙烯酸酯光交联的效果

合成了曙红(EO)二苯基碘鎓盐(DPIO)复合光引发体系,其光响应范围可至可见光区,最大吸收527nm。曙红鎓盐体系无暗反应,但在可见光作用下,由于光诱导电子转移敏化反应使染料发生漂白作用和鎓盐裂解产生活性自由基,由此可引发环氧6101双丙烯酸酯和季戊四醇三丙烯酸酯的光固化。光固化速度与复合体系的结构组成有关,其中曙红双盐(EO(Ph_I)_2)比曙红单盐(EO(Ph_2I))具有更高的引发效率;在同样条件下双分子体系(EONa_2+Ph_2I+BF_4~-)不能引起交联反应。     

三苯基烷基硼盐作引发剂的染料光敏聚合

三苯基烷基硼盐作引发剂的染料光敏聚合陈汉清，李妙贞，汪秀智，常志英，王尔鉴（中国科学院感光化学研究所北京１００１０１）关键词染料光敏作用，三苯基烷基硼盐，高分子光聚合近年来，光诱导电子转移光解反应已在光敏聚合方面得到重要应用’‘’，作者过去已报道了采...     

离子对内电子转移型染料阴离子-翁盐阳离子光敏体系中的溶剂效应和结构效应

本文研究了溶剂效应和结构效应对染料碘翁盐光物理, 光化学性质的影响。观察到在溶剂中离子对可以各种形式存在, 如紧密离子对、溶剂分隔离子对或溶剂化的自由离子, 溶剂的极性不仅影响各种存在形式的光谱性质, 而且影响它们之间的平衡关系, 进而影响离子对体系的物理化学性质。染料母核和碘翁阳离子的结构均对离子对体系的性质有影响。光诱导电子转移反应的热力学驱动力越大, 反应速度越快。用分子模拟技术(Molecular Modeling)对离子对体系的立体结构进行了研究, 为理解离子对体系的各种物理化学行为提供了重要的参考。     

荧烷染料/二芳基碘鎓盐同步光生色和光聚合体系

荧烷染料(FR)和二芳基碘盐(On⁺X^-)组成的体系,在光作用下,通过激发态的荧烷染料与碘盐之间发生电子转移反应,生成开环结构的荧烷染料有色体,伴随发生盐的光解反应,生成活性引发自由基碎片。该体系不仅可有效地引发烯类单体的聚合反应,也可同步发生光生色作用,产生较高的色密度。进一步研究了二芳基碘盐的取代基不同碳链长度和不同对离子及浓度诸因素,在光固化体系中对生色反应的影响。同时FR/On⁺X^-体系引发光交联形成的有色薄膜具有良好的色稳定性。     

呫吨染料－双(二苯基碘鎓盐)在高分子膜中的光谱和光化学特性

近年来,在迅速发展的新材料中,许多品种是与激光技术和光化学反应密切相关的。而目前使用最多的光源为氩离子激光,He-Ne激光和半导体激光,因此开发可见光和近红外区有灵敏响应的光敏体系已成为十分迫切的问题。由于染料品种多,易得到,具有广泛的可选择性,因而染料光敏化反应体系再度引起人们的重视。     

方酸菁染料/二芳基碘鑑盐体系引发丙烯酸酯光交联反应

近年来随着高新技术的迅猛发展,激光技术和光化学也随之大量应用到先进材料中,为适应这种发展需要,开发感可见光和近红外光的光敏反应体系已成为十分迫切的研究课题［１,２］．方酸类染料是一类重要的功能性染料,广泛地应用于静电复印、太阳能电池和光记录材料［３］...     

A mechanistic investigation of a three‐component radical photoinitiator system comprising methylene blue,N‐methyldiethanolamine,and diphenyliodonium chloride

Three‐component systems, which contain a light‐absorbing species (typically a dye), an electron donor (typically an amine), and a third component (usually an iodonium salt), have emerged as efficient, visible‐light‐sensitive photoinitiators. Although three‐component systems have been consistently found to be faster and more efficient than their two‐component counterparts, these systems are not well understood and a number of distinct mechanisms have been reported in the literature. In this contribution, photodifferential scanning calorimetry and in situ, time‐resolved, laser‐induced, steady‐state fluorescence spectroscopy were used to study the initiation mechanism of the three‐component system methylene blue, N‐methyldiethanolamine and diphenyliodonium chloride. Kinetic studies based upon photodifferential scanning calorimetry reveal a significant increase in polymerization rate with increasing concentration of either the amine or the iodonium salt. However, the laser‐induced fluorescence experiments show that while increasing the amine concentration dramatically increases the rate of dye fluorescence decay, increasing the DPI concentration actually slows consumption of the dye. We concluded that the primary photochemical reaction involves electron transfer from the amine to the dye. We suggest that the iodonium salt reacts with the resulting dye‐based radical (which is active only for termination) to regenerate the original dye and simultaneously produce a phenyl radical (active in initiation) derived from the diphenyliodonium salt. © 2000 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 38: 2057–2066, 2000     

Effect of Self-association and Protein Binding on the Photochemical Reactivity of Triarylmethanes. Implications of Noncovalent Interactions on the Competition between Photosensitization Mechanisms Type I and Type II

We have explored the photochemical behavior of cationic triarylmethane dye monomers and dimers free in solution and noncovalently bound to bovine serum albumin (BSA) and examined how self-association and the formation of host-guest complexes involving biopolymers and photosensitizers affect the competition between the photosensitization type I and type II mechanisms. Our results have clearly indicated that tri-para-substituted triarylmethane dyes bind efficiently to albumin as monomers and dimers and, interestingly, that the formation of dye aggregates in aqueous solutions is actually assisted by the protein. Protein-assisted dye aggregation takes place under conditions of high biopolymer loading (high [dye]/[protein] ratios), as attested by the appearance of a hypsochromically shifted absorption band (H-band) that overlaps with the spectral shoulder of the respective dye monomer. As predicted by the molecular exciton theory, the intersystem crossing efficiency in H-type dimers is expected to be higher than in the respective dye monomers, and photoinduced electron transfer events are intrinsically favored in dye aggregates as a result of the physical contact between donor and acceptor. We have found that when triarylmethanes are noncovalently bound to BSA their photoreactivity undergoes a remarkable enhancement, and that the photooxidation mechanism type I is particularly favored in the macromolecular environment. A comparative examination of the behavior of triarylmethane dyes with that of methylene blue have shown that in the case of methylene blue the binding phenomenon also favor the type I mechanism.     

EPR study on the photosensitized generation of reactive oxygen species by actinomycin D

Actinomycin D (AMD) is an anticancer antibiotic that can bind selectively to both double-stranded and single-stranded DNA, and this binding greatly enhances DNA photosensitization. Using electron paramagnetic resonance (EPR) in combination with spin trapping techniques, a systematic study was carried out on the reactive oxygen species generated in the photosensitization process of AMD. It was found that 1O2 and O2- are important reactive intermediates either insolution or in DNA complexes, and the generation of these species is in competition. This finding suggests that the photodynamic action of AMD proceeds via two pathways: energy transfer (type Ⅰ mechanism) and electron transfer (type Ⅱ mechanism). 1O2 is the main product formed via energy transfer reaction in solution while electron transfer between the excited states of AMD and DNA becomes the predominant pathway in DNA complexes.     

Photoinduced electron transfer at the polymer-solution interface. II. Effects of ionic environment

Three types of polymer electron transfer sensitizer were prepared by copolymerization of 1-pyrenylmethyl methacrylate with styrene (I), vinylbenzyltriethylammonium chloride (II), and sodium p-styrenesulfonate (III). Irradiation of the pyrenyl group in the presence of leuco crystal violet (LCV), in homogeneous or in heterogeneous systems, induced the formation of crystal violet cation (CV⁺) in air. The reactivity of I, II, and III was in the order of II > I > III in both systems; this was rationalized in terms of the Coulombic effect. The effect of charge is much greater for the heterogeneous systems. High-charge density on the polymer surface and enhanced polymer-solvent affinity account for the high reactivity of II. The high quantum efficiency, coupled with the advantage of facile product separation, warrants the practical application of interfacial sensitization.