N-甲基丙烯酰-N′-嘧啶基哌嗪及其聚合物敏化的丙烯腈光聚合

我们曾报道过同一分子中含有给电子生色基团和电子受体基团的一类功能性单体,如甲基丙烯酸-4-N,N-二甲氨基苄酯(DMABMA),N-(4-N′,N′-二甲氨基苯基代丙烯酰胺,N-(4-N′、N′)-二甲氨基苯基代甲基丙烯酰胺(DMAPMA),8-丙烯酰氧喹啉(AQ),N-丙烯酰-N′-苯基哌嗪(APP)的合成、聚合以及单独或与过氧化二酰构成氧化还原体系以引发烯类单体的聚合研究。N-甲基丙烯酰-N′-嘧啶基哌嗪(MPMP)     

N-甲基-N-(2-甲基丙烯酰氧乙基)苯胺与其聚合物的荧光光谱

<正> 我们曾报道过甲基丙烯酸-4-N,N-二甲氨基苄酯(DMABMA)、N-(4-N′N′-二甲氨基苯基)代丙烯酰胺(DMAPMA)、8-丙烯酰氧喹啉(AQ)、N-丙烯酰-N′-苯基哌嗪(APP)等在同一分子中含有缺电子双键和给电子发色基团的单体及它们的聚合物在溶液中的荧光行为。在相同的链节克分子浓度下,这些单体的荧光强度比其聚合物的荧光强度低很多。我们将这种现象称为“结构自猝灭现象”。这种现象是由于共存在这类     

8-丙烯酰氧喹啉及其聚合物增感的丙烯腈光聚合

<正> 我们曾研究过电子给体基团和电子受体基团共存于同一分子中的一类功能性单体,如甲基丙烯酸-4-(N,N)-二甲氨基苄酯(DMABMA)、N-(4-N′,N′-二甲氨基苄基)丙烯酰胺(DMAPAA)、8-丙烯酰氧喹啉(AQ)。N-丙烯酸-N′=苯基哌嗪(APP)等     

N-甲基丙烯酰-N′-嘧啶基哌嗪及其聚合物的荧光光谱研究

我们曾报道过N-丙烯酰-N′-苯基哌嗪(APP)的合成、聚合、荧光性质及其单独或与过氧化物构成氧化还原体系以引发烯类单体聚合的研究。由于APP是分子中含有给电子生色基团和缺电子双键的丙烯酸类衍生物,其荧光表现有结构自猝灭现象并且聚合物的荧光也能被其它缺电子烯类单体如丙烯腈所淬灭。对于分子中含有多个氮原子的芳杂环叔胺丙烯酸类单体的研究,文献报道较少。本文合成了新的功能性单体N-甲基丙烯酰-N′-嘧啶基哌嗪(MPMP),并观察了单体及其聚合物溶液的荧光光谱。     

8-羟基喹啉的丙烯酸酯及其聚合物的荧光光谱研究

在同一分子中既含有电子给体基团,又含有电子受体基团的单体,如甲基丙烯酸二甲氨基苄酯(DMABMA),N-(4-N′,N′-二甲氨基苯基)代丙烯酰胺(DMAPAA)及其聚合物的荧光光谱颇为有趣。     

N-甲基-N-(2-甲基丙烯酰氧乙基)苯胺敏化的丙烯腈光聚合

含有芳香叔胺基的烯类单体如N,N-二甲氨基苯乙烯,N-4-N',N'-二甲氨基苯基代丙烯酰胺(DMAPAA),N-4-N',N'-二甲氨基苯基代甲基丙烯酰胺(DMAPMA),甲基丙烯酸-4-N,N-二甲氨基苄酯(DMABMA),8-丙烯酰氧喹啉(AQ)等不仅与过氧化物构成氧化还原引发体系以引发其它烯类单体的光聚合还可以作为光敏剂引发烯类单体的光聚合。由于这类功能性单体在同一分子中既含有缺电子双键基团又含有供电子生     

以β-二酮连接的含生色团丙烯酰类单体及其饱和模型化合物的荧光行为

通过合成一系列同一分子中既含有给电子性荧光生色团又含缺电子性碳碳双键的烯类单体, 发现这类单体在相同生色团浓度下的荧光强度均明显低于相应的饱和模型化合物或聚合物[1～3]. 这种现象称为荧光结构自猝灭效应(SSQE), 以区别于浓度自猝灭现象. 对于电子状态与之相反的单体, 即含受电子性荧光生色团的乙烯基醚类单体, 也观察到了SSQE[4,5]. 进一步的研究结果表明, SSQE是光照条件下分子内电子给受体之间电荷转移作用的结果, 分子中电子给受体间的间隔基长度和溶剂的性质等都对SSQE有显著的影响[6]. 以往合成的含给生色团的丙烯酰类单体, 其电子给受体间是通过饱和脂肪链相连, 当生色团和受电子性碳碳双键之间以β-二酮结构相连时, 这类单体的荧光性质如何, 是否发生SSQE是我们的关注所在. 另一方面, β-二酮类化合物在一定波长光照射条件下, 常发生烯醇式与酮式的互变异构化. 虽然已有许多文献报道有关烯醇式-酮式互变异构过程中各种光谱的变化以及用核磁、红外、紫外等光谱手段研究烯醇式-酮式互变异构动力学, 但有关β-二酮类化合物互变异构过程中荧光光谱的变化的报道却很少[7～11]. 本文合成了以β-二酮连接的含二甲氨基苯基生色团的烯类单体, 1-(4-二甲氨基苯基)-4-甲基-4-戊烯-1,3-二酮(DMPDK)及其饱和模型化合物1-(4-二甲氨基苯基)-1,3-丁二酮(DMBDK), 研究了其光谱性质及光致互变异构行为.     

含有给电子生色团的双马来酰亚胺与脂肪二胺的共聚合及其荧光光谱跟踪

我们曾合成了一系列含有给电子生色团的丙烯酰类单体 ,它的给电子本质主要是由氮原子 ,以Ｎ ,Ｎ 二甲基氨基苯基的形式所贡献[1～ 4] ,即 :Ｎ ( 4 Ｎ′,Ｎ′ 二甲氨基苯基 )马来酰亚胺 ,Ｎ ( 4 Ｎ′ ,Ｎ′ 二甲氨基苯基 )丙烯酰胺 ,Ｎ ( 4 Ｎ′ ,Ｎ′ 二甲氨基苯基 )衣康酰胺 ,甲基丙烯酸 (对 4 Ｎ ,Ｎ 二甲氨基 )苄酯 ,这些单体的荧光发射强度总是远远低于相同浓度聚合物的荧光强度 .为了区别所熟知的荧光浓度自猝灭 ,我们称这种现象为结构自猝灭效应 (ＳＳＱＥ) [1～ 5] .具有ＳＳＱＥ的丙烯酰类单体可表示为Ａ( =) Ｄ( ) 型化合物 …     

含胺基功能性单体的聚合研究——ⅫⅠ.丙烯腈在N-丙烯酰-N′-苯基哌嗪及其聚合物作为增感剂下的光聚合

关于含有芳香叔胺基的烯类单体,我们曾报道过N,N-二甲氨基苯乙烯,N-(4—N′,N′-二甲氨基苯基代丙烯酰胺(DMAPAA),N-(4-N′,N′-二甲氨基苯基代甲基丙烯酰胺(DMAPMA),甲基丙烯酸-4-N,N-二甲氨基苄脂(DMABMA),8-丙烯     

受体-给体-受体型双马来酰亚胺衍生物的合成及其荧光行为

对于含有给电子生色团的丙烯酰类单体和含有受电子生色团的乙烯氧基类单体的荧光行为以及光敏和光引发聚合行为 ,我们进行了长期系列的研究 [1～ 4 ] .含有给电子生色团的丙烯酰类单体可表示为A(=) - D(* ) 型单体 ,A(=) 表示受电子丙烯酰双键 ,D(* ) 表示给电子生色团 .反之 ,含有受电子生色团的乙烯氧基类单体可表示为 D(=) - A(* ) 型单体 ,D(=) 表示给电子乙烯氧基双键 ,A(* ) 表示受电子生色团 .在相同浓度下 ,这些单体的荧光强度总是远远低于其聚合物或相应饱和模型化合物的荧光强度 .为了区别于众所周知的浓度自猝灭 ,我们称这种…     

Atom transfer radical polymerization of a novel quinoline derivative monomer and fluorescent property

A novel functional monomer incorporating quinoline derivative moiety as the side group, 2-[4-(2,7,7-trimethyl-3-ethoxycarbonyl-5-oxo-1,4,5,6,7,8-hexhydricquinoline)phenoxyl] ethylmethacrylate (HQPEMA), was synthesized and polymerized utilizing atom transfer radical polymerization (ATRP) technique. 2-(4-Chloromethylphenyl)benzoxazole (CMPB) and CuCl/PMDETA were used as the initiator and catalyst, respectively. GPC, ¹H NMR and fluorescent emission spectroscopy were conducted for characterization of polymers. The linear increase of number average molecular weight (M_n) versus conversion and the relatively narrow molecular weight distribution (M_w/M_n) of the obtained polymers confirmed that ATRP of HQPEMA was carried out successfully. In addition, the fluorescence “structural self-quenching effect” was observed in the DMF solution of the monomer HQPEMA, which bearing both electron-donating chromophore group and electron-accepting CC bond. We also found that the fluorescence properties of the newly obtained polymers containing quinoline chromophore depended on both the monomer concentration in solution and the polarity of solvents. The emission of the polymer film showed that the emission peak maxima of the polymer film shifted 50 nm towards high wavelength with respect to the polymer in DMF solution due to the intermolecular or intramolecular interactions of the polymer chains.     

Synthesis,crystal structures,and photophysical properties of dibromo-2-(2′-pyridyl)imidazole and its corresponding boron–fluorine complex

2-(2′-Pyridyl)imidazole L1 and its corresponding boron–fluorine complex, 1, were synthesized and their crystal structures correlated with their photophysical properties. L1 forms a rigid supramolecular network through hydrogen bonds and halogen bond in the single crystal, which induces amplified spontaneous emission in crystals; it emits rather poor fluorescence in solution and powder states. Its boron chelate 1 emits intense fluorescence in solution since boron chelate is an excellent chromophore, and it exhibits large Stokes shift (136?nm in acetonitrile), due to the charge-transfer transition from the electron-donating π system to the electron-accepting boron moiety. Interestingly, 1 is also highly fluorescent in amorphous powder and crystal states; C–C rotation between pyridyl and imidazole groups is inhibited by the formation of a five-member ring containing BF₂, and the formation of intermolecular non-covalent bonds is the key factor. Solid emission with large Stokes shift makes it a valuable chromophore for synthesis of functional materials.     

A low-energy-gap organic dye for high-performance small-molecule organic solar cells

A novel donor-acceptor-acceptor (D-A-A) donor molecule, DTDCTB, in which an electron-donating ditolylaminothienyl moiety and an electron-withdrawing dicyanovinylene moiety are bridged by another electron-accepting 2,1,3-benzothiadiazole block, has been synthesized and characterized. A vacuum-deposited organic solar cell employing DTDCTB combined with the electron acceptor C(70) achieved a record-high power conversion efficiency (PCE) of 5.81%. The respectable PCE is attributed to the solar spectral response extending to the near-IR region and the ultracompact absorption dipole stacking of the DTDCTB thin film.     

It takes more than an imine: the role of the central atom on the electron-accepting ability of benzotriazole and benzothiadiazole oligomers

We report on the comparison of the electronic and photophysical properties of a series of related donor-acceptor-donor oligomers incorporating the previously known 2H-benzo[d][1,2,3]triazole (BTz) moiety as the acceptor and the recently reported BTzTD acceptor, a hybrid of BTz and 2,1,3-benzothiadiazole (BTD). Although often implied in the polymer literature that BTz has good acceptor character, we show that this moiety is best described as a weak acceptor. We present electrochemical, computational, and photophysical evidence supporting our assertion that BTzTD is a strong electron acceptor while maintaining the alkylation ability of the BTz moiety. Our results show that the identity of the central atom (N or S) in the benzo-fused heterocyclic ring plays an important role in both the electron-accepting and the electron-donating ability of acceptor moieties with sulfur imparting a greater electron-accepting ability and nitrogen affording greater electron-donating character. We report on the X-ray crystal structure of a BTzTD trimer, which exhibits greater local aromatic character in the region of the triazole ring and contains an electron-deficient sulfur that imparts strong electron-accepting ability. Additionally, we examine the transient absorption spectra of BTzTD and BTz oligomers and report that the BTz core promotes efficient intersystem crossing to the triplet state, while the presence of the thiadiazole moiety in BTzTD leads to a negligible triplet yield. Additionally, while BTz does not function as a good acceptor, oligomers containing this moiety do function as excellent sensitizers for the generation of singlet oxygen.     

Turning on fluorescent emission from C-alkylation on quinoxaline derivatives

Reduction on imine moiety (C=N) of quinoxalines by alkyl-/aryllithiums led to a geometrical change on the quinoxaline ring, thereby perturbing the electronic structure to turn on fluorescence emission. Such a structural change resulted in interrupted cyclic-ring systems with electron-donating amine (sp(3)-type) and electron-accepting imine (sp(2)-type) units bridged by a phenylene unit. Through either alkylation or arylation, a highly polarized electron donor-electron acceptor bipolar system was established in a single molecule with dramatically enhanced PL efficiency (up to 60%).     

Photodissociative Modules that Control Dual-Emission Properties in Donor–π–Acceptor Organoborane Fluorophores

Donor–π–acceptor fluorophores that consist of an electron-donating amino group and an electron-accepting triarylborane moiety generally exhibit substantial solvatochromism in their fluorescence while retaining high fluorescence quantum yields even in polar media. Herein, we report a new family of this compound class, which bears ortho-P(=X)R₂-substituted phenyl groups (X=O or S) as a photodissociative module. The P=X moiety that intramolecularly coordinates to the boron atom undergoes dissociation in the excited state, giving rise to dual emission from the corresponding tetra- and tricoordinate boron species. The susceptibility of the systems to photodissociation depends on the coordination ability of the P=O and P=S moieties, whereby the latter facilitates dissociation. The intensity ratios of the dual emission bands are sensitive to environmental parameters, including temperature, solution polarity, and the viscosity of the medium. Moreover, precise tuning of the P(=X)R₂ group and the electron-donating amino moiety led to single-molecule white emission in solution.     

含生色基团烯类单体及其聚合物——N－丙烯酰基吩■嗪及其聚合物的合成和其荧光性质

含生色基团烯类单体及其聚合物——Ｎ－丙烯酰基吩嗪及其聚合物的合成和其荧光性质＊于淑艳姚光庆李福绵（北京大学化学系北京１００８７１）关键词Ｎ－丙烯酰基吩嗪,紫外－可见光谱,荧光光谱,“结构自猝灭”效应,Ｓｔｅｒｎ－Ｖｏｌｍｅｒ常数,荧光寿命我们曾报...     

Self-assembled fluorescent hexaazatriphenylenes that act as a light-harvesting antenna

In this paper we report the self-assembling nature of fluorescent hexaazatriphenylenes (HATs) 6a-d with six alkyl/alkoxy-chain-containing biphenyl groups and their application to light-harvesting antennae. In a nonpolar solvent and the film state, the HAT derivatives form one-dimensional aggregates with an H-type parallel stacking mode, which were analyzed by 1H NMR, UV-vis, and steady-state and time-resolved fluorescence spectroscopy. When HAT derivative 7 with six perylenediimide moieties is incorporated into the one-dimensional aggregates, an efficient energy transfer takes place from the self-assembled HAT moiety as a light-harvesting antenna to the perylenediimide moiety as an energy acceptor. Further, when HAT derivative 8 with six triphenylamino moieties is newly added to the light-harvesting system, an intermolecular electron transfer occurs subsequently between the electron-accepting perylenediimide molecule and the electron-donating triphenylamino molecule.     

Intramolecular charge-transfer interactions in pi-extended tetrathiafulvalene derivatives

New electron-donor (D)-electron-acceptor (A) TTF architectures are presented in which two electron-donating 1,3-dithiole moieties are connected by a pi bridge to the weak electron-accepting quinoxaline moiety (D-pi-A compounds 9a and 9b and also two 1,3-dithiole-2-ylidene moieties are connected by a pi bridge to the electron-accepting thieno[3,4-b]quinoxaline bridge (D-pi-A-pi-D compounds 12a-c). There are through-bond intramolecular charge-transfer (ICT) interactions, predicted in theoretical calculations, and confirmed by UV-vis spectroscopy and cyclic voltammetry measurements. This work constitutes the first use of quinoxalines as electron-accepting moieties in D-pi-A compounds.