带不同推电子基团二聚苯撑乙的电子结构与发光性能

用Ｗｉｔｔｉｇ路线合成了一系列带不同推电子取代基的二苯撑乙烯,用紫外光谱和循环伏安方法测定其电子结构,并用量子化学计算方法对齐聚物的电子能级进行模拟,讨论了吸收光谱,发射光谱与生色团的电子结构的叛乱     

杂原子取代卟啉的电子结构和光谱

用INDO/CI法计算了等电子氧杂、硫杂、氮杂卟啉的电子结构及低激发态电子跃迁.从前线轨道特征、电荷分布等与自由卟啉对比讨论了杂原子取代卟啉的电子结构.计算结果还预期了一些杂原子取代卟啉的低激发态电子跃迁光谱.     

偶氮染料分子的电子结构与生物降解活性(Ⅰ)——电荷分布对偶氮键还原裂解的影响

用量子化学MNDO方法计算了不同结构类型的偶氮染料分子的电子结构.与厌氧活性污泥对偶氮双键生物降解实验结果对照分析后发现,分子电子结构中,电荷分布的对称性对偶氮键生物降解活性有重要影响.并通过LUMO_lp(具有反应部位氮原子孤电子对特征的最低空轨道)及分子偶极矩阐述了电子结构与生物降解活性的关系.     

HSO自由基电子基态激发态的CAS计算研究

使用CASSCF方法和ANO-L基组优化了HSO自由基的基态和3个低占据激发态的结构, 并采用包括更多电子动态相关能的CASPT2方法进行了单点能校正. 频率计算结果表明, 优化的4个几何为势能面上的稳定点. 通过电子结构的研究合理地解释了各个激发态相对于电子基态的结构变化.     

聚磷氮烯及其衍生物电子结构的理论研究

用分子轨道和晶体轨道方法,对聚磷氮烯及其衍生物的电子结构进行了研究,以期更深入地了解聚磷氮烯的结构和性能.研究发现,链状聚磷氮烯和环状三聚磷氮烯为平面结构,其它的环状聚磷氮烯则为巢式结构,吸电子基团取代有使环状聚磷氮烯主链环取平面结构的倾向.研究还发现,无论是链状还是环状聚磷氮烯,都表现为半导体.取代基效应表明,吸电子基团-F和-CN的取代,使聚合物的电子亲和势(EA)和电离能(IP)均增大,能隙减小,给电子基团-CH₃和-OCH₃的取代,使聚合物的IP减少;吸电子基团取代有利于n-型掺杂,给电子基团取代有利于p-型掺杂,但都不改变其半导体的特性.     

[2~3]Cyclophanes电子结构的理论研究

用改造的重叠模型多重散射X~α自洽场方法计算环芳类化合物[2~3]cyclophanes的电子结构, 分析该类分子中分子轨道通过空间和通过键的相互作用,单键连接桥.双键连接桥对通过键相互作用的影响, 用过渡态理论方法计算分子前线分子轨道的电离能,理论结果与紫外光电子能谙符合较好.     

荧光素及其衍生物电子结构与光谱性质的理论研究

用ZINDO、从头算和密度泛函理论方法研究荧光素及其衍生物的电子结构和光谱性质.计算结果表明母体双阴离子荧光素分子(1)与单(2)、双(3)取代形成的单阴离子荧光素分子的基态电子结构不同,而且1与2和3的基态和激发态的电子转移方向相反.体系1~3的最大吸收波长依次发生红移,与实验结果相符合.     

四层过渡金属夹心化合物的电子构型

本文利用共点稠合型硼烷的拓扑结构规则和EHMO量子化学计算方法, 讨论了四层过渡金属夹心化合物的电子构型, 以及它与几何结构之间的关系. 用于解释实际化合物的电子构型. 继而, 对四层、三层和双层夹心化合物的电子构型与几何结构之间的关系进行了比较和讨论.     

超细钛金属线的电子性质

使用第一性原理方法计算研究了一系列无限长、 超细的钛金属线的结合能和电子性质, 并得到了这些超细金属线的电导. 结果表明, 超细钛金属线单位原子的结合能比体材料的结合能低得多, 而且与金属线截面半径的倒数在所计算的纳米范围内成线性反比关系. 钛金属线的电子结构性质表现出渐进的尺寸演化和明显的结构关联, 当金属线直径大于1 nm时表现出类似体材料的电子结构, 这与Ti团簇的电子结构性质相似. 对电导的计算发现, 金属线的电导随着线尺寸的变粗而增大, 电导通道的数目由金属线的结构对称性和粗细所决定.     

缺电子联吡啶环蕃与富电子苯醚链的结合能

采用分子动力学方法模拟了缺电子联吡啶环蕃(CPQT)和不同富电子苯醚链分子形成的准轮烷在乙腈溶液环境下的结构和相互作用. 分别利用AM1和密度泛函理论(DFT)的B3LYP/6-31+g方法优化了环蕃分子的结构, 并将获得的电荷导入分子动力学软件中. 通过计算发现, CPQT和不同富电子苯醚链分子的结合能大小排序为BHEEB·CPQT>BHEB·CPQT>1/4DMB·CPQT. 随着温度的升高, 富电子苯醚链在环蕃中运动加剧, 准轮烷稳定性下降, 计算结果与实验结果一致.     

Armchair型石墨纳米带的电子结构和输运性质

利用第一性原理的电子结构和输运性质计算方法, 研究了扶手椅(armchair)型单层石墨纳米带(具有锯齿边缘)的电子结构和输运性质及其边缘空位缺陷效应. 研究发现, 完整边缘的扶手椅型石墨纳米带是典型的金属性纳米带, 边缘空位缺陷的存在对扶手椅型纳米带能带结构有一定的影响,但并不彻底改变其金属性特征.     

Spectroscopic,structure and DFT studies of palladium(II) complexes with pyridine-type ligands

Five palladium(II) complexes with pyridine derivative ligands have been synthesized. The molecular structures of the complexes were determined by X-ray crystallography, and their spectroscopic properties were studied. Based on the crystal structures, computational investigations were carried out in order to determine the electronic structures of the complexes. The electronic spectra were calculated with the use of time-dependent DFT methods, and the electronic spectra of the transitions were correlated with the molecular orbitals of the complexes. The emission properties of the complexes have been examined.     

高分子阴离子电导的研究

制备了含Ｉ＾－榻解质薄膜,用阻抗谱法测量了样品的Ｉ＾－电导率,分析了样品的频响特性曲线,用Ｗａｇｎｅｒ直流极化法测量了样品的电子电导。实验发现,此阴离子导体几乎和相应的含Ｎａ＾＋有相同的离子电导率,且随着碘含量的增加, 率增大。离子电导实验结果表明,在此阴离子导体中,电子电导占总电导率的９％,而空穴的导导率比电子电导率小１￣２个数量级。     

Ligand electronic effects in the palladium catalyzed asymmetric allylic alkylation reaction with planar chiral diphosphine-oxazoline ferrocenyl ligands

A series of planar chiral diphosphine-oxazoline ferrocenyl ligands with different electronic properties were successfully used in the asymmetric allylic substitutent reaction. The enantioselectivity of this reaction was affected by the electronic nature of the ligands. When the electronic effect was coincident with the steric effect of ligand, a higher ee value was observed.     

Etude quantique des etats electroniques des nitramines Part I. Etat fondamental et premier état triplet

(Quantum study of the electronic states of nitramines. Part I. Study of the ground state and first electronic triplet state)

The structure of the nitramide in its electronic ground state and its first electronic triplet state was calculated. The computations were carried out at the SCF level with the 4-31G* basis set. The double-well potential surfaces of these two states were investigated as a function of the N---N bond length and the inversion angle. The barrier height was calculated without, and with, a full optimization of the plane structure.     

Determination of indoor air quality of a phytosanitary plant

Effective fermentation monitoring is a growing need due to the rapid pace of change in the wine industry, which calls for fast methods providing real time information in order to assure the quality of the final product. The objective of this work is to investigate the potential of non-destructive techniques associated with chemometric data analysis, to monitor time-related changes that occur during red wine fermentation. Eight micro-fermentation trials conducted in the Valtellina region (Northern Italy) during the 2009 vintage, were monitored by a FT-NIR and a FT-IR spectrometer and by an electronic nose and tongue. The spectroscopic technique was used to investigate molecular changes, while electronic nose and electronic tongue evaluated the evolution of the aroma and taste profile during the must-wine fermentation. Must-wine samples were also analysed by traditional chemical methods in order to determine sugars (glucose and fructose) consumption and alcohol (ethanol and glycerol) production. Principal Component Analysis was applied to spectral, electronic nose and electronic tongue data, as an exploratory tool, to uncover molecular, aroma and taste modifications during the fermentation process. Furthermore, the chemical data and the PC1 scores from spectral, electronic nose and electronic tongue data were modelled as a function of time to identify critical points during fermentation. The results showed that NIR and MIR spectroscopies are useful to investigate molecular changes involved in wine fermentation while electronic nose and electronic tongue can be applied to detect the evolution of taste and aroma profile. Moreover, as demonstrated through the modeling of NIR, MIR, electronic nose and electronic tongue data, these non destructive methods are suitable for the monitoring of must-wine fermentation giving crucial information about the quality of the final product in agreement with chemical parameters. Although in this study the measurements were carried out in off-line mode, in future these non destructive techniques could be valid and simple tools, able to provide in-time information about the fermentation process and to assure the quality of wine.     

Theoretical study of atoms by the electronic kinetic energy density and stress tensor density

The electronic structure of atoms in the first, second, and third periods were analyzed using the electronic kinetic energy density and stress tensor density, which are local quantities motivated by quantum field theoretic consideration, specifically the rigged quantum electrodynamics. The zero surfaces of the electronic kinetic energy density, which are called as the electronic interfaces, of the atoms were computed. It was found that their sizes exhibited clear periodicity and were comparable to the conventional atomic and ionic radii. The electronic stress tensor density and its divergence, tension density, of the atoms, were also computed and how their electronic structures were characterized by them was discussed. © 2016 Wiley Periodicals, Inc.     

基于噻吩和亚苯基合成的新物质的结构和电子性质

Theoretical study on the geometries and electronic properties of new conjugated compounds based on thiophene and phenylene was carried out. The theoretical ground-state geometries and electronic structures of the studied molecules were obtained using the density functional theory (DFT) method at B3LYP level with 6-31G(d) basis set. The electronic properties were determined by ZINDO/s, CIS/3-21G(d), and TD//B3LYP/3-21G(d) calculations performed on the B3LYP/6-31(d) optimized geometries. The effects of the ring structure and the substituents on the geometries and electronic properties of these materials were discussed. The results of this study indicate how the electronic properties can be tuned by the backbone ring or side group and suggest these compounds as good candidates for opro-electronic applications.     

Structural and Electronic Properties of New Materials Based on Thiophene and Phenylene

Theoretical study on the geometries and electronic properties of new conjugated compounds based on thiophene and phenylene was carried out. The theoretical ground-state geometries and electronic structures of the studied molecules were obtained using the density functional theory (DFT) method at B3LYP level with 6-31G(d) basis set. The electronic properties were determined by ZINDO/s, CIS/3-21G(d), and TD//B3LYP/3-21G(d) calculations performed on the B3LYP/6-31(d) optimized geometries. The effects of the ring structure and the substituents on the geometries and electronic properties of these materials were discussed. The results of this study indicate how the electronic properties can be tuned by the backbone ring or side group and suggest these compounds as good candidates for opto-electronic applications.     

单壁碳纳米管的电子速度及有效质量

利用单壁碳纳米管(SWCNTs)能量色散关系, 计算了最低导带的电子速度和有效质量, 重点讨论了SWCNTs中最低导带电子速度和有效质量与波矢及管径大小的关系. 结果表明, 半导体型锯齿SWCNTs的电子速度和有效质量与其结构参量(管径)有直接的关系. 各种椅型SWCNTs(金属型)和金属型锯齿SWCNTs最低导带电子速度和有效质量随波矢的变化规律分别相同, 各种半导体型锯齿SWCNTs最低导带电子速度和有效质量随波矢的变化规律则有明显差别. 这意味着在低偏压下, 不同管径的椅型SWCNTs和金属型锯齿SWCNTs输运性能相同, 而各种不同管径半导体型锯齿SWCNTs输运性能有明显差别.