若干新型有机光电功能材料的分子设计、合成与性能 研究

介绍本研究组得到国家自然科学基金资助的四个方面工作的进展。研究了金属有机化合物的结构与非线性光学性质的关系,总结了从分子几何构型着手,根据不同用途,对金属有机非线性光学材料进行分子设计的经验规律;提出了利用“组合式共轭桥”进行有机非线性光学发色团分子设计的新思路,所合成的几个有机化合物既有很大的光学非线性,又有紫移的最大吸收峰;通过化学键将有机发色团分子张到各种高分子的侧链上,合成和表征了潜在的电光高分子和光折变高分子材料;采用无机-有机夹层复合的思路对兼有导电性和强磁性的分子材料进行了探索,将一些有机小分子和导电高分子分别插入了层状无机物MPS3的层间,得到了8个新的分子磁体,而另一夹层化合物则表现了较高的电导率。     

钼磷酸和2-吡啶-偶氮-2萘酚电荷转移配合物的合成、表征及性质研究

杂多化合物具有很强的接受电子能力,是一类优秀的受体分子,它可以与有机分子以氢键或配位键作用形成电荷转移配合物。由于这类配合物具有特殊的光、电、磁性质在催化、功能材料及药物化学等领域受到研究者的广泛关注[1]。有大量文献报道了杂多酸作为电子受体与有机给体相结合形成电子给一受型配合物,并在性能方面进行了探讨[2-3]。为了考察有机配体的位阻效应对配合物形成的影响,我们选择体积大,含有偶氨基及共轭π键的2-吡啶- 偶氮-2-萘酚（简写为PAN）为电子给体,12-钼磷酸（简写为PMo12）为电子受体,制备了新型标题化合物,并对…     

2-对乙酰氨基苯基-4,5-二对硝基苯基咪唑的合成及性能

咪唑化合物;非线性光学活性有机化合物;2-对乙酰氨基苯基-4;5-二对硝基苯基咪唑的合成及性能     

含1,3-二硫-2叶立德烯的系列有机发色团的二阶非线性光学性质的理论研究

设计了12个含有1,3-二硫-2叶立德烯的具有二阶非线性光学性质的有机发色团,对所研究分子用AM1方法进行几何构型优化,用INDO/CI方法获得基态到各激发态的垂直跃迁能和振子强度,即电子光谱;在此基础上用SOS公式计算系列分子的二阶非线性光学系数β_ijk,并从微观上对这一系列分子进行比较,为进一步探索综合性能较好的NLO有机物提供了理论指导.     

5,11,17,23-四叔丁基-25,26,27,28-四[3-(甲氧基羰基)苄氧基]杯[4]芳烃包合性能的研究

杯芳烃是继冠醚和环糊精后的第三代主体化合物 .这类主体分子不仅可以识别和络合阳离子 ,而且还具有包合中性有机分子的性能 [1～ 5] .杯 [4]芳烃类包合物的晶体结构测定表明 ,它们可分为分子内和分子间包合两种类型 [3 ,5] ,前者是客体分子被包合在主体分子的空穴内 ,后者是客体分子被包合在主体分子之间 .对叔丁基杯 [4]芳烃的下沿酚氧基与上沿均可进行化学修饰得到不同的杯 [4]芳烃衍生物 .最早报道的对叔丁基杯 [4]芳烃及其衍生物的分子内包合物是与甲苯或乙腈的 1∶ 1包合物 [4 ,5] ,客体分子依靠 CH3 -π的作用被包结在主体分子内[6]…     

小型计算机的Hückel分子轨道(HMO)计算方法会话程序

量子化学近似计算方法中,Hückel分子轨道(HMO)计算方法简便迅捷,它对分析有机共轭分子的稳定性、化学反应能力和电子光谱,及其研究有机化合物结构与性能的关系都适用。目前在有机化学、药物化学和生物化学领域中得到广泛的应用。     

9-苯基芴-4-三苯胺电致发光材料的光电性质

采用HF方法和DFT/B3LYP方法对一种新型的含芴三苯胺,即9-苯基芴-4-三苯胺有机化合物进行了基态结构全优化,CIS方法获得分子最低激发态结构,并采用TD-DFT方法计算分子的吸收光谱和发射光谱.计算结果表明,该分子从基态到激发态的跃迁,几何结构变化主要表现在分子中心三苯胺中苯环和N原子之间的二面角上,吸收及发射光谱的计算结果与实验值一致,吸收光谱为324.52nm,发射光谱为379.01nm,荧光寿命较长,为60.6637ns,是优良的典型蓝色有机电致发光材料.     

7-氯-[1，2，3，4]-四氢吩嗪-[2，3]-并富勒烯[60]的合成

60富勒烯及其衍生物因其结构的特殊性,在有机超导、分子磁性、有机发光材料、分子器件、非线性光学活性、能量代谢和生物活性等[1]方面表现出独特的性能和潜在的应用前景,是非常活跃的研究领域之一.     

脱氯化氢法合成聚(2,5-二乙氧基对苯乙炔)

聚对苯乙炔（ＰＰＶ）及其衍生物具有独特的光电性能，经强氧化剂掺杂后是一类重要的导电材料［１］，而且具有良好的非线性光学（ＮＬＯ）性质［２］，也是目前为止性能最好的电致发光材料［３］，因而ＰＰＶ及其衍生物的合成成为电致发光领域研究的热点之一。目前国内外...     

N,N-二(N-亚甲基-2-吡咯烷酮)丙氨酸(C13H21N3O4)的结构和配位性能

N,N二 (N亚甲基 2吡咯烷酮 )丙氨酸是我们最近合成的一个新化合物（如图 1所示）,经 X射线衍射实验测定了它的晶体结构,得到了其结构数据。实验结果表明它与稀土离子及其邻菲咯啉形成的配合物具有光致变色的性能。针对该柔性分子具有较复杂的三维构型结构, 为了更好地研究该化合物与金属离子的配位性能,我们基于量子化学 AM1方法的计算结果,从标题化合物分子的几何构型、能量特性、电荷布居、前线分子轨道特征等方面研究了该化合物的配位性能,并与实验进行了比较。 1计算方法 本文根据常见的键长键角数据作为初始化参数…     

Study of Linear and Nonlinear Optical Properties of Four Derivatives of Substituted Aryl Hydrazones of 1,8‐Naphthalimide

Four 1,8‐naphthalimide hydrazone molecules with different electron‐donating groups have been applied in the study of linear and nonlinear optical (NLO) properties. These compounds showed strong green emission in solution. Their NLO properties such as two‐photon absorption (TPA) behavior with femtosecond laser pulses ca. 800 nm and excited‐state absorption (ESA) behavior with nanosecond laser pulses at 532 nm were investigated. Compound 4 presented the largest two‐photon cross section (550 GM) among them due to two factors: the conjugated length of compound 4 is the longest and the electron‐donating ability of compound 4 is the strongest. Different from TPA behavior, compound 2 showed the best nonlinear absorption properties at 532 nm and its nonlinear absorption coefficient and third‐order nonlinear optical susceptibilities χ ⁽³⁾ were up to 1.41×10^?10 MKS and 4.65×10^?12 esu, respectively. Through the modification of the structure, the nonlinear optical properties of these compounds at different wavelengths (532 and 800 nm) were well tuned. The great broad‐band nonlinear optical properties indicate hydrazones are good candidates for organic nonlinear optical absorption materials.     

几种查耳酮的二阶非线性光学性质解析

合成了一系列的查耳酮衍生物,系统地测量了其ＳＨＧ（二次谐波产生）效率和截止吸以长,并用ＣＮＤＯ／Ｓ－ＣＩ方法计算了它们的二阶非线性光学系数β值。通过对这些化合物性质的分析发现：（１）取代基Ｂｒ不仅能有效地增强微观非线性能能有效地增强材料的宏观非线性效应。（２）取代基Ｂｒ有利于改善材料的透光性能的和热稳定性;（３）分子在晶体中的空间取向是影响材料宏观非线性的另一个重要因素。     

Synthesis and optical properties of bis(oligophenyleneethynylenes)

Bis(oligophenyleneethynylenes) 1-4 were prepared as representative members of a new class of potential nonlinear optical materials. The optical properties of 1-4 were examined for evidence of restricted rotation of the aryl rings when compared to their single-strand precursors, which could potentially increase their nonlinear response through more effective conjugation. The effect of altering the electron density of the terminating functional group of these compounds on their properties was also investigated.     

Organic Polymeric and Non-Polymeric Materials with Large Optical Nonlinearities

Nonlinear optical properties are a sensitive probe of the electronic and solid-state structure of organic compounds and as a consequence find various applications in many areas of optoelectronics including optical communications, laser scanning and control functions, and integrated optics technology. Because of their strongly delocalized π electronic systems, polymeric and non-polymeric aromatic compounds show highly nonlinear optical effects. Nowadays, polymer chemists are able to tailor specific materials properties for various applications. Some organic substances with π electronic systems exhibit the largest known nonlinear coefficients, often considerably larger than those of the more conventional inorganic dielectrics and semiconductors, and thus show promise for thin-film fabrication, allowing the enormous function and cost advantages of integrated electronic circuitry. The electronic origins of nonlinear optical effects in organic π electronic systems are reviewed, with special emphasis being given to second-order nonlinear optical effects. Methods for measuring nonlinear optical responses are outlined, and the critical relationships of the propagation characteristics of light to observed nonlinear optical effects and to solid-state structure are discussed. Finally, the synthesis and characterization of organic crystals and polymer films with large second-order optical nonlinearities are summarized.     

Influence of Metal Complexing on the Nonlinear-Optical Properties of Compounds with High Molecular Symmetry

Coordination bonding of 1,5-diphenylpentadienone was studied with the aim to prepare compounds exhibiting third-order nonlinear optical properties. The volume resistivity of these compounds was studied as influenced by the third-order nonlinear susceptibility tensor.     

Theoretical study on the second-order nonlinear optical properties of asymmetric spirosilabifluorene derivatives

The equilibrium geometries of four asymmetric spirosilabifluorene derivatives are optimized by means of the DFT/B3LYP method with the 6-31G* basis sets in this paper. On the basis of the optimized structures, the electronic structure and second-order nonlinear optical properties are calculated by using time-dependent density-functional theory (TDDFT) based on the 6-31G* level combined with the sum-over-states (SOS) method. The results show that these compounds possess remarkably larger molecular second-order polarizabilities than typical organometallic and organic compounds, and replacement of a carbon atom with nitrogen within the conjugated substituent has a great influence on the second-order nonlinear optical properties. Analysis of the main contributions to the second-order polarizability suggests that charge transfer from the z-axis directions plays a key role in the nonlinear optical response. These compounds have a possibility to be excellent second-order nonlinear optical (NLO) materials from the standpoint of large beta values, small dipole moment, high transparency, and small dispersion behaviors.     

端炔丙基化合物的聚合反应研究进展

端炔丙基化合物的聚合产物以其优异电导性,非线性光学特性等性能而引起人们的广泛兴趣,本文了近年来端炔丙基化合物的氧化聚合、易位聚合、自由基聚合、缩聚等聚合的研究进展。     

含硫原子簇化合物的三阶非线性光学性质

总结近年来Mo(W，V)／S／Cu(Ag，Au)含硫原子簇化合物的三阶非线性吸收与非线性折射等光学性质的研究状况，Mo(W，V)／S／Cu(Ag，Au)含硫原子簇化合物的结构与光学性质之间的关系。     

Dependence of the two-photon absorption cross section on the conjugation of the phenylacetylene linker in dipolar donor-bridge-acceptor chromophores

The nonlinear optical properties of four isomeric dipolar two-photon chromophores are compared. The chromophores consist of a carbazole electron donor coupled to a naphthalimide electron acceptor by a phenylacetylene bridge. By variation of the connectivity of the bridge at the phenyl groups, four compounds with 0, 1, and 2 meta linkages are synthesized. The linear and nonlinear optical properties of these compounds are measured. Despite similar linear absorption cross sections, the two-photon absorption cross section delta of the all-meta compound is almost a factor of 10 lower than the all-para compound. By taking the detailed molecular conformations into account in order to calculate accurate dipole moment changes, we find that the decrease in delta results largely from the decreased charge transfer ability with increasing number of meta linkages. We find that a two-state model can be used to predict semiquantitatively the observed trend in delta on the basis of the linear optical properties of the molecules. This work illustrates the dramatic effect the ground-state polarizability can have on the nonlinear optical response of organic compounds and also provides a way to quantify the ability of meta linkages to inhibit charge transfer in their ground-state configuration.