荧光素与紫精、咔唑分子内的光致电子转移反应

合成了以-(CH_2)_4连接的荧光素、紫精、咔唑二元及三元化合物,运用吸收光谱,荧光光谱及荧光寿命研究了荧光素-咔唑、紫精-荧光素、紫精-荧光素-咔唑等二元、三元化合物分子内的光致相互作用,结果表明:分子内紫精对荧光素荧光的淬灭主要通过形成不发荧光的络合物,荧光淬灭的效率φ_Q为0.97,荧光寿命淬灭的效率φ_(ET)为0,不发荧光络合物的淬灭的效率φ_C为0.97.咔唑对荧光素荧光的淬灭则以动态的光致电子转移过程为主,荧光淬灭的效率φ_Q为0.63,荧光寿命淬灭的效率φ_(ET)也为0.63,不发荧光络合物的淬灭效率φ_C为0.在三元化合物内紫精-荧光素和荧光素-咔唑对光致相互作用是一种竞争过程,以荧光素-咔唑对间的动态电子转移反应为主,φ_Q为0.97,φ_(ET)为0.65,不发荧光络合物的淬灭效率φ_C为0.32.从反应自由能变化的角度对此进行了讨论.     

以共价键相连的卟啉-酞菁化合物分子内能量传递及光诱导电子转移

合成了叶啉与酞菁以共价键连接起来的双发色团分子。测定了它们的吸收光谱,荧光光谱,荧光寿命等。计算了分子内能量传递过程的效率(φ_EnT)及速率常数(κ_EnT)。结果表明:在稀溶液中,卟啉与酞菁等克分子混合时,观察不到分子间能量传递过程现象的发生;而双发色团分子的分子内能量传递过程则明显发生了,其效率(φ_EnT=13～70%)与速率常数(κ_EnT=1.2×10⁷～2.0×10⁸s^-1)取决于分子的结构类型。电子转移与能量传递过程与介质性质有关。在极性溶剂中有利于电子转移过程的进行,而不利于能量传递过程;在非极性溶剂中,则有利于能量传递过程的进行,而不利于电子转移。 选择性激发酞菁发色团,观测到了只有电子转移发生的过程,其电子转移效率达到38%。     

曙红与卟啉分子间和分子内的光致相互作用

合成了以半刚性链(一CH_2phCH_2—)和柔性链(—(CH_2)_4—)连接的曙红-卟啉二元化合物及其模型化合物.通过吸收光谱、荧光光谱、激发光谱及荧光寿命研究了模型化合物分子间的相互作用和二元化合物分子内的光致电子转移和能量传递.结果表明:二元化合物的模型化合物曙红乙酯和卟啉易形成基态复合物 在二元化合物分子内激发曙红时,曙红能将其单重态能量传递给卟啉,并能引发分子内的电子转移;激发卟啉时,能发生曙红向卟啉的电子转移.分析了分子构型和溶剂极性对2种过程的影响.     

新型卟啉-酞菁二元分子内光物理过程的研究

合成了以哌嗪连接的含卟啉－酞菁的双发色团分子，测定了它的吸收光谱，荧光光谱和荧光寿命。并计算了在不同溶剂中两发色团之间的能量传递效率ΦＥｎＴ和电子转移效率ΦＥＴ。结果表明：在非极性溶剂苯中，两发色团之间的光物理过程以激发态单线态能量传递为主（ΦＥｎＴ８０％）。而在极性溶剂ＤＭＦ中，则以电子转移为主（ΦＥＴ６９．８％）。该二元化合物在ＤＭＦ中，哌嗪以船式构象存在，我们以前合成的以氧或柔性链连接的二元     

电子给体-电子受体体系的合成及分子内光致电荷转移反应的研究

论文中设计,合成了以9,10-二甲氧基蒽(DMA)为电子给体,双酚A(BA)为连接体,连接不同的电子受体(对苯甲酸乙酯,对腈基苯,2,4-二氧苯,对硝基苯,蒽醌AQ,2,4-二硝基苯)的六种二元分子,测定了它们的氧化还原电位,吸收光谱,荧光光谱,荧光寿命等。研究了它们的分子内光致电子转移过程,研究了它们的分子内光致电子转移反应自由能的变化△G与电子转移速率常数K_q的关系。     

细菌光合反应中心Q~A和Q~B间电子转移反应的量子化学研究

用量子化学半经验的AM1和密度泛函DFT(BELYP/6-31G(d))方法分别优化了质体醌MQ1(Q~A)、泛醌UQ1(Q~B)及其阳离子自由基的结构。用Nelsen方法计算了电子转移反应MQ1-UQ1→MQ1UQ^-~1的内重组能λi。用线性反应坐标方法构造了该电子转移反应的双势阱,两透热势能面在反应坐标R≈0.30处相交。对该电子转移体系进行闭壳层的单点计算,并用Koopmans定理计算了体系的分裂能△,得到△随线性反应坐标R的变化关系。结果表明,在R=0.342处△有一极小值,从而得到该电子转移反应的电子转移矩阵元Vrp,并由此确定了反应的过渡态。在此基础上,用两球模型计算了反应的溶剂重组能λ0。本文还计算了该电子转移反应的活化自由能△G。最后,根据Marcus电子转移理论计算了该反应的速率常数ket为5.93×10^4s^-^1,由此得到该反应的半衰期与文献报道的结果一致。     

氮氧自由基的研究——Ⅷ.关于溶剂极性经验参数的讨论

作者测定了有机溶剂-水二元混合溶剂体系中2,2,6,6-四甲基哌啶-1-氧自由基(TMPO)的ESRa_N 值.这类混合溶剂体系中 a_N-m 关系可归属有机二元混合溶剂体系的四种典型线型关系.比较了几种溶剂极性经验参数,说明各种经验极性参数-m 关系图的差异是特定模型反应中溶剂分子与溶质分子间相互作用不同的反映.对二元混合溶剂体系而言,a_N-E_T(30),a_N-Z 一般不具有线性关系,认为溶剂极性经验参数是溶剂(包括溶剂混合物)对模型化合物溶剂化能力的标度,给出了在各种溶剂体系中的 a_N 测定值,作为溶剂对中性偶极分子相对溶剂化能力的经验标度.     

给体-受体体系分子内光致电子转移反应研究

对一类以9，10－二甲氧基蒽为给体，双酚A为连接链连接不同受体的电子给体－受体体系，通过单光子计数法测定荧光寿命，计算了各体系内的光致电子转移反应速率常数，通过测定氧化还原电位，计算出各电子给体－受体体系电子转移反应的自由能变化．并根据电子转移反应理论对光致电子转移速率常数与自由能变化关系进行了理论计算分析，发现本文各体系的光致电子转移速率常数的实验值与电子转移反应理论曲线吻合得比较好，同时也揭示在该类给体－受体体系中未出现电子转移反转区的原因在于电子转移过程自由能变化（－ΔG）没有足够大。     

联苯负离子自由基与萘分子间长程电子转移的从头算研究

分离处理π σ π体系中的给体 ,受体和σ桥体 ,在HF/4 31G和HF/DZP水平上优化了联苯 ,联苯负离子自由基 ,萘和萘负离子自由基的几何构型 ,计算了分子间电子转移的内重组能 .取线性反应坐标R =0 .5 ,在STO 3G水平上用变分原理和分子轨道跃迁能方法 ,计算了π σ π体系自交换反应的电子转移矩阵元 .对交叉反应体系 ,沿线性反应坐标搜寻最小轨道能级分裂Δmin,确定了电子转移矩阵元和过渡态构型 .用Marcus双球模型计算液相电子转移的溶剂重组能 ,结合半经典模型计算了几种以联苯负离子自由基为给体 ,联苯和萘为受体的π σ π体系分子内电子转移速率常数 .     

有机配体Schiff碱4-(2-羟基苯基)-亚氨基-戊-2-酮的从头算研究

本文通过从头算HF／6－31G（d）方法,对Schiff4－（2－羟基苯基）－亚氨基－戊－2－酮 进行了理论研究,提供了该化合物两种互变异构体的几何构型参数、电子结构、IR光谱性 、偶极矩数据,并借助热、动力学手段,分析了两种互变异构体的异构平衡过程。计算结果表明：（1）从几何构型、电子 结构和相对能量的角度考虑,由于较强的分子内氢键作用和较大的共轭体系,亚胺烯醇式更为稳定。（2）从分子极性的角度考虑,烯胺酮式具有较大的偶极矩,其较强的分子间作用力有利形成晶体,因而烯胺酮式以晶体的形式存在。（3）由烯胺酮式向亚胺烯醇式转化的互变异构反应是热力学自发反应,但受到较大活化能的控制,是一个动力学稳定体系。分析了极性溶剂存在的互变异构反应是热力学自发反应,但受到较大活化能的控制,是一个动力学稳定体系。分析了极性溶剂存在将有利于反应发生且标题化合物以亚胺烯醇式存在于极性溶剂中的作用。以上结论均与实验研究结果相符。     

Polarity effects on the photophysics of dendrimers with an oligophenylenevinylene core and peripheral fullerene units

Highly soluble dendritic branches with fullerene subunits at the periphery and a carboxylic acid function at the focal point have been prepared by a convergent approach. They have been attached to an oligophenylenevinylene (OPV) core bearing two alcohol functions to yield dendrimers with two, four or eight peripheral C60 groups. Their photophysical properties have been systematically investigated in solvents of increasing polarity; that is, toluene, dichloromethane, and benzonitrile. Ultrafast OPV-->C60 singlet energy transfer takes place for the whole series of dendrimers, whatever the solvent. Electron transfer from the fullerene singlet is thermodynamically allowed in CH2Cl2 and benzonitrile, but not in apolar toluene. For a given solvent, the extent of electron transfer, signaled by the quenching of the fullerene fluorescence, is not the same along the series, despite the fact that identical electron transfer partners are present. By increasing the dendrimer size, electron transfer is progressively more difficult due to isolation of the central OPV core by the dendritic branches, which hampers solvent induced stabilization of charge separated couples. Compact structures of the hydrophobic dendrimers are favored in solvents of higher polarity. These structural effects are also able to rationalize the unexpected trends in singlet oxygen sensitization yields.     

Energy transfer followed by electron transfer(ETET) endows a TPE-NBD dyad with enhanced environmental sensitivity

Energy transfer and electron transfer are both fundamental mechanisms enabling numerous functional materials and applications. While most materials systems employ either energy transfer or electron transfer, the combined effect of energy and electron transfer processes in a single donor/acceptor system remains largely unexplored. Herein, we demonstrated the energy transfer followed by electron transfer(ETET) process in a molecular dyad TPE-NBD. Due to energy transfer, the fluorescence of TPE-NBD was greatly enhanced in non-polar solvents. In contrast, polar solvents activated subsequent electron transfer and markedly quenched the emission of TPE-NBD. Consequently, ETET endows TPE-NBD with significant polarity sensitivities. We expect that employing ETET could generate many functional materials with unprecedented properties, i.e., for single laser powered multicolor fluorescence imaging and sensing.     

蒈烯芳氰敏化光氧化反应的研究——Ⅰ.蒈烯对9,10-二腈基蒽荧光的猝灭特性

本文通过研究在不同溶剂中蒈烯对9,10-二腈基蒽(DCA)荧光猝灭的光物理特性及溶剂极性对猝灭速度的影响,温度效应的测定及其在乙腈中双分子猝灭速率常数k_q值与计算所得自由能的变化(△G)之间的关系符合 RehmWeller关系,证明了菇烯对DCA荧光的猝灭是一个电子转移的动态猝灭过程。     

Solvent effect on the charge transfer complex of oxatomide with 2,3-dichloro-5,6-dicyanobenzoquinone

The charge transfer complex (CT-complex) between oxatomide drug and 2,3-dichloro-5,6-dicyanobenzoquinone (DDQ) was studied spectrophotometrically in 10 solvents at different temperatures. The donor oxatomide is found to form stable 1:1 stoichiometric complex with DDQ and the stoichiometry was unaffected by change in polarity of the solvent studied. The DeltaH degrees, DeltaS degrees and DeltaG degrees values are all negative, so the studied complex is reasonably stable and exothermic in nature. The ionization potential of the drug was determined using the CT-absorption bands of the complex in all the solvents. The dissociation energy of the charge transfer excited state for the CT-complex in different solvents was also determined and is found to be constant. The spectroscopic and thermodynamic properties were observed to be sensitive to the nature of the solvent.     

Spectral-luminescent and solvatochromic properties of 2-(3-coumarinyl)-5-(2′-(R-amino)-phenyl)-1,3,4-oxadiazoles

Spectral-luminescent properties of the newly synthesized 2-(3^′-coumarinyl)-5-(2′-(R-amino)-phenyl)-1,3,4-oxadiazoles has been investigated in solvents of various polarity and hydrogen-bonding ability. It has been found that for all the studied compounds no excited state intramolecular proton transfer occurs despite the presence of coumarinyl fragment - electron acceptor effect of the coumarinyl fragment is not sufficient to increase the excited state acidity of the amino group. It has been found that the absorption spectra of the studied compounds shift to higher energy with increase in solvent polarity, whereas corresponding fluorescence spectra shift to lower energy with solvent polarity increase. It has been suggested that long-wavelength shifts of the fluorescence spectra of the studied compounds with increase in solvent polarity is caused by the solvent relaxation. The observed solvent relaxation effect allow us to propose some of the studied compounds as potential probes to monitor changes in solvent relaxation in low-polar media and as potential probes for rigidochromic effect.     

SOLVENT DEPENDENCE OF PYRIMIDINE DIMER SPLITTING IN A COVALENTLY LINKED DIMER-INDOLE SYSTEM

Cyclobutadipyrimidines (pyrimidine dimers) undergo splitting that is photosensitized by indole derivatives. We have prepared a compound in which a two-carbon linker connects a dimer to an indolyl group. Indolyl fluorescence quenching indicated that the two portions of the molecule interact in the excited state. Intramolecular photosensitization of dimer splitting was remarkably solvent dependent, ranging from phi spl = 0.06 in water to a high value of phi spl = 0.41 in the least polar solvent mixture examined, 1,4-dioxane-isopentane(5 : 95). A derivative with a 5-methoxy substituent on the indolyl ring behaved similarly. These results have been interpreted in terms of electron transfer from the excited indolyl group to the dimer, which would produce a charge-separated species. The dimer anion within such a species could split or undergo back electron transfer. The possibility that back electron transfer is in the Marcus inverted region can be used to rationalize the observed solvent dependence of splitting. In the inverted region, the high driving force of a charge recombination exceeds the reorganization energy of the solvent, which is less for solvents of low polarity than those of high polarity. If this theory is applicable to the hypothetical charge-separated species, a slower back electron transfer, and consequently higher splitting efficiencies, would be expected in solvents of lower polarity. Photolyases may have evolved in which a low polarity active site retards back transfer of an electron and thereby contributes to the efficiency of the enzymatic dimer splitting.     

Effect of Solvent Polarity on Excited-State Double Proton Transfer Process of 1, 5-Dihydroxyanthraquinone

The excited-state double proton transfer (ESDPT) properties of 1, 5-dihydroxyanthraquinone (1, 5-DHAQ) in various solvents were investigated using femtosecond transient absorption spectroscopy and the DFT/TDDFT method. The steady-state fluorescence spectra in toluene, tetrahydrofuran (THF) and acetonitrile (ACN) solvents presented that the solvent polarity has an effect on the position of the ESDPT fluorescence emission peak for the 1, 5-DHAQ system. Transient absorption spectra show that the increasing polarity of the solvent accelerates the rate of excited state dynamics. Calculated potential energy curves analysis further verified the experimental results. The ESDPT barrier decreases gradually with the increase of solvent polarity from toluene, THF to ACN solvent. It is convinced that the increase of solvent polarity can promote the occurrence of the ESDPT dynamic processes for the 1, 5-DHAQ system. This work clarifies the mechanism of the influence of solvent polarity on the ESDPT process of 1, 5-DHAQ, which provides novel ideas for design and synthesis of new hydroxyanthraquinone derivatives.     

Dual fluorescence of omeprazole: effect of solvents and pH

Absorption, steady state fluorescence and time-resolved fluorescence spectra of omeprazole (OMP) have been studied in solvents of different polarity and pH. With an increase in the polarity of the solvents, blue shift is observed in the longer wavelength whereas red shift is noticed in the shorter wavelength band. The dual emission observed in non-polar solvents suggests that the energy of the twisted intramolecular charge transfer (TICT) state is lower than that of the locally excited (LE) state. The normal Stokes-shifted band originates from the LE state, and the large Stokes-shifted band is due to the emission from a TICT state. The Stokes shift of OMP is correlated with various solvent polarity scales like E_T(30) and f?(D,n).     

Oligo(p-phenyleneethynylene)-functionalized Perylenebisimidetriad: Synthesis, Photophysical Properties, and Self-assembly

The rod‐like oligo(p‐phenylene ethynylene)‐functionalized perylene bisimide triad was synthesized and characterized. Aggregation behavior in solvents of different polarity was investigated by absorption and fluorescent spectroscopy. The results showed that stronger aggregations took place in low‐polarity slovent. The experiments also indicated that the energy and electron transfer might takeplace between the two chromophores during the photoinduced excitation. Highly ordered two‐dimensional assemblies could be observed at solid/liquid interfaces.     

吩噻嗪给体受体衍生物激发态的电荷转移

A series of N-bonded donor-acceptor derivatives of phenothiazine containing phenyl （PHPZ）, anisyl （ANPZ）, pyridyl （PYPZ）, naphthyl （NAPZ）, acetylphenyl （APPZ）, and cyanophenyl （CPPZ） as an electron acceptor have been synthesized. Their photophysical properties were investigated in solvents of different polarities by absorption and emission techniques. These studies clearly revealed the existence of an intramolecular charge transfer （ICT） excited state in the latter four compounds. The solvent dependent Stokes shift values were analyzed by the modified Lippert-Mataga equation to obtain the excited state dipole moment values. The large excited state dipole moment suggests that the full （or nearly full） electron transfer take place in the A-D systems. In the system of A-D phenothiazine derivatives, the transition dipole moments Mflu were determined mainly by direct interactions between the solvent-equilibrated fluorescence ^1CT state and ground state because of their lack of significant change with increase of the solvent polarity. The electron structure and molecular conformation of phenothiazine derivatives will be significantly changed with the increase of the electron affinity of the N-10 substituent.