噻吩衍生物电子结构的DFT研究

采用B3LYP方法在6-31G^*水平上优化了12种α位取代噻吩衍生物的几何构型，采用TD-DFT方法计算了它们的前线轨道能级和电子光谱．结果表明，a，f和1分子比它们的同分异构体要稳定；噻吩衍生物与苯、吡啶相比，也具有很好的共轭性；随着分子中所连接基团数目的增多，特别是-CN的增加，分子的偶极距增大，前线轨道能级差减小，分子的最大吸收波长发生红移；对于具有相同共轭链的同分异构体，c，g，k分子的偶极距较大，而前线轨道能级差最小的分别为b，e，1分子，相应的最大吸收波长也较大．这些结论对分子设计具有重要的指导意义．     

给、吸电子基团对吡嗪衍生物电子结构影响的DFT研究

采用B3LYP方法在6—31G^#基组水平上优化了对位取代吡嗪衍生物的几何构型，利用TD—DFT方法计算了它们的前线分子轨道能级和电子光谱．结果表明，带有给、吸电子基团对吡嗪衍生物与苯、吡啶相比，也具有很好的共轭性；随着分子共轭链的增长，分子的偶极矩增大，前线分子轨道能级差减小，最大吸收波长发生红移．对于具有相同共轭链的同分异构体，推电子基团与具有给电子性质的共轭链相连，则分子的电荷转移明显，导致偶极矩增大，前线分子轨道能级间的电子跃迁更容易；吸电子基团与具有给电子性质的共轭链相连，情况正好相反，这些结果对分子设计有重要意义。     

多胺基烷基酰胺生成机理的量子化学研究

用量子化学方法研究了丙酸与多乙烯多胺缩合反应机理。采用AM1方法全优化计算了丙酸多胺盐及其质子化盐的几何构型、电子结构以及酸催化下的亲核加成和消除反应的机能曲线,求得该两步反应的活化能分别为6.258kJ/mol和206.15kJ/mol。消除反应是速度控制步骤。发现质子化后丙酸羰基碳原子上的净电荷增大,前线分子轨道能级差减小,前线分子轨道间相互作用增强,表明酸催化大大增强反应活性。     

五味子素A、B和五味子丙素的密度泛函研究

采用密度泛函B3LYP方法在6-31G基组水平上对五味子素A、B及五味子丙素3种五味子提取物进行了优化计算,并从平衡几何构型、前线分子轨道、净电荷分布等方面对计算结果做了比较.计算结果表明分子中的二氧五环对分子的药物活性具有较大影响.随着分子中二氧五环数目的增加,分子中联苯环扭转角减小,前线轨道能级和能级差都减小,联苯环上正电荷增加,由此可判断3种分子活性顺序应为五味子丙素>五味子素B>五味子素A.     

中心对称吡嗪衍生物电子光谱和三阶非线性光学性质的理论计算研究

采用量子化学abinitio HF和半经验ZINDO-SOS方法计算了吡嗪及其衍生物的电子光谱和三阶非线性光学系数.结果表明,中心对称的吡嗪衍生物随着体系共轭链的增长,最大吸收谱线波长增大,前线轨道能级差减小,体系的三阶非线性光学系数增大;引入取代基后可改变其三阶非线性光学性质.在相同骨架中引入吸电子基团-NO₂形成A-π-A共轭结构,其三阶非线性光学系数比引入供电子基-NH₂的体系大.     

推/拉电子取代基对PCBM结构及光谱性质影响的理论研究

应用密度泛函理论(DFT)方法计算[6,6]-苯基-C₆₁-丁酸甲酯(PCBM)及其苯环对位取代得到的4种衍生物的几何和电子结构. 采用第一激发能校正了分子的最低未占据分子轨道(LUMO)能级, 探讨了推/拉电子基团对分子前线轨道的影响. 在全优化几何构型的基础上, 采用含时密度泛函理论(TD-DFT)方法研究了电子吸收光谱特征和电荷转移态性质, 并讨论了推/拉电子基团对体系电子吸收光谱性质的影响. 通过对重组能和电子亲和势的计算, 预测了PCBM与4种衍生物的电子能力及电子迁移率大小的关系. 结果表明, 在PCBM中, 在苯环的对位引入推电子基团可以提高分子的前线轨道能级, 改变前线轨道电子云分布, 明显增强可见光范围内的吸收强度, 增加可见光范围内的电荷转移吸收, 且激发态的电荷转移随着引入基团推电子能力的增加而增强. 化合物5的激发态分子内电荷转移性质最强, 且具有较独特的光伏性质. 而在同样位置引入拉电子基团, 则降低了分子前线轨道能级对电子吸收光谱的影响.     

半花菁衍生物分子非线性光学性质的理论研究

采用有限场(FF)/PM3方法对半花菁衍生物的第一超极化率和分子前线轨道性质进行了计算.结果表明,半花菁衍生物分子的第一超极化率主要与D-π-A结构有关,σ-烷基链对分子第一超极化率的影响很小,并且分子第一超极化率与分子前线轨道HOMO和LUMO能级差ΔEHL呈较好的线性关系.     

硝基芳烃对圆腹雅罗鱼毒性的DFT研究

对30种硝基芳烃化合物进行DFT-B3LYP/6-311G**水平全优化计算, 据所得量子化学参数分类建立了硝基苯类和硝基苯胺类化合物对圆腹雅罗鱼急性毒性(－lgEC₅₀)的定量构效关系(QSARs)模型. 结果表明, 硝基苯类化合物的毒性主要由硝基基团的电荷(Q_-NO2)和前线轨道能级差(ΔE)决定; 硝基苯胺类化合物的毒性则由分子最低未占轨道能级(E_LUMO)和ΔE决定. 苯环上取代基的类型、数目和取代位置直接影响到标题化合物的毒性大小, 强吸电子基如硝基会降低Q_-NO2和E_LUMO大小, 使化合物毒性增强, 且邻对位硝基取代的毒性高于间位取代; 相反, 给电子基团氨基的存在则会使化合物的毒性降低. 总之, 硝基是这两类化合物致毒的主要基团, 将硝基包覆或还原为氨基应为此类化合物解毒的重要途径. 最后以1,4-二硝基苯为例, 模拟了其活性亚硝基中间产物与蛋白质中还原性巯基间的反应, 并将其与硝基苯和1,3-硝基苯的反应活化能进行了比较, 讨论了不同取代基数目和位置对分子活性的影响, 结果与QSAR模型分析一致, 进一步验证了硝基芳烃化合物的致毒历程, 研究结果对品优高能炸药的分子设计也有助益.     

给、吸电子基团对芳香共轭体系电子结构影响的密度泛函理论研究

采用密度泛函理论,在B3LYP／6—31G^＊方法水平上对8个连接有给、吸电子基团的芳香共轭体系的稳定性、偶极矩、静电荷分布和前线轨道能级进行了研究,并采用TD／DFT方法进一步研究了它们的电子光谱．结果表明a-1,b-1,c-1和d-2分子比它们的同分异构体要稳定;对于苯、呋喃、吡咯与乙烯形成的共轭体系,吸电子基团连接在乙烯一端,给电子基团连接在芳香环上使体系的偶极距增强,而吡啶则相反;前线轨道能级差较小的是吸电子基团连接在芳香环一端的体系,相应的分子最大吸收波长也较大．     

以苯等芳香环桥联的1,3-二硫杂环戊二烯衍生物的NLO性质

采用密度泛函理论(DFT)B3LYP/6-31G*优化一系列以芳环为桥联基团,1,3-二硫杂环戊二烯为供电子基团,丙二氰为吸电子基团的D-π-A型分子的几何结构,在此基础上对分子的极化率和第一超极化率进行计算.结果分析表明,桥联苯环数的增加,供电子基团(—OCH3)的引入及共轭桥的增长对分子的几何构型影响很小,但能使分子的二阶非线性光学(NLO)系数增加,且分子的最大吸收波长发生红移.甲氧基的引入或共轭桥的增长,分子的前线分子轨道能级差减小,TD-DFT计算表明分子深层占有轨道与空轨道之间的电子跃迁对二阶NLO效应也有较明显贡献.     

电场对Ni3（dpa）4Cl2金属串配合物结构影响的理论研究

应用密度泛函UBP86方法对具有分子导线潜在应用性的金属串配合物Ni3(dpa)4Cl2进行研究,分析了外电场对配合物的几何构型和电子结构的影响.结果表明,零电场条件下存在沿着Ni63+轴及轴向配体Cl的Ni—Ni及Ni—Cl离域作用.沿金属轴Cl4→Cl5方向施加外电场,可使高电势端的Ni2—Cl4键长增大而Ni1—Ni2键长减小,低电势端的Ni3—Cl5键长减小而Ni1—Ni3键长增大;分子能量降低,偶极矩线性增大;HOMO与LUMO能隙减小,前线占据轨道分布向低电势方向移动且轨道能升高,空轨道分布则向高电势方向移动且轨道能降低,其中沿着金属轴方向离域的前线轨道分布及其轨道能随电场的变化尤为显著.在电场作用下,电荷分布发生改变,低电势端Cl5的负电荷向高电势端Cl4转移,但金属和桥联配体的电荷变化很小;同样,在电场作用下,配合物存在明显的结构变化和电子转移现象,呈现出类似导电过程中电子定向转移的变化规律.     

8-羟基喹啉铍及其衍生物电子光谱性质的含时密度泛函理论研究

运用密度泛函理论(DFT)B3LYP方法和abinitioHF单激发组态相互作用(CIS)法分别优化了有机金属配合物8-羟基喹啉铍(BeQ₂)及其3种衍生物分子的基态及最低激发单重态几何结构.系统分析了分子结构、前线分子轨道特征和能级分布规律以探索电子跃迁机理.应用含时密度泛函理论(TD-DFT)计算分子的电子光谱,揭示了BeQ₂及其衍生物的发光源于配体中π→π^*电子跃迁,指出通过配体修饰可以有效地影响配合物前线分子轨道分布,调整发光波段,并有效提高电荷转移量.     

Optical and Electrical Properties of Triphenylamine Derivatives for Dye-sensitized Solar Cells and Designing of Novel Molecule

With density functional theory(DFT) method, the optimization of molecular configurations and the calculation of frontier molecular orbitals were achieved for triphenylamine(TPA)-based dye-sensitized solar cell materials at the B3LYP/6-31G(d, p) level. Time-dependent density functional theory(TD-DFT) was applied to calculating the probability of the transition from the ground state to the excited state. And UV-Vis absorption spectra were derived with Franck-Condon approximation. The conjugation length, substitution groups and spatial effects show a slight influence on the dihedral angle of the TPA group. The increase of conjugation length may cause a smaller energy gap as well as a higher highest occupied molecular orbital(HOMO) and a lower lowest unoccupied molecular orbital (LUMO). The introduction of methoxyl group and TPA group could lower the energy gap while the HOMO and LUMO were elevated in energy.     

Electronic and optical properties of edge modified peritetracene: a DFT study

Peritetracene (PTA) molecules have promising applications in organic electronics and organic light-emitting diodes, but the major constraints come from their poor stability with higher energy gap. We have investigated the stability, electronic, and optical properties of different electron-donating- and electron-withdrawing-substituted PTA molecule groups using density functional theory (DFT) and time-dependent density functional theory (TDDFT) methods. On substituting suitable electron donor and acceptor groups, the energy gap of PTA molecules reduces up to 0.37 eV with an increase in their stability. The stabilities of considered PTA molecules have been investigated using the distribution pattern of frontier molecular orbital energies. The charge transfer properties with smaller ionization potential and larger electron affinity for PTA molecule have been evaluated using Koopmans’ theorem. Enhancement in dipole moment, polarizability, and hyperpolarizability of PTA substituted with electron-donating groups shows the presence of NLO properties. Also, we have investigated the spectroscopic properties of different electron-donating- and electron-withdrawing-substituted PTA molecule groups. Our spectroscopic properties show the bathochromic shift and small hypsochromic shifts in wavelengths of PTA with substituents groups. It is therefore concluded that the –NCH₃ and –NO₂ substituent groups on PTA are observed to have the strongest and highest stability than the other substituent groups considered.

     

取代基对依布硒啉电子结构及光谱性质影响的理论研究

采用密度泛函理论B3LYP方法在6-311++G**水平对依布硒啉及其6个衍生物进行结构优化,并分析了取代基对分子几何构型、电荷分布、前线轨道能级分布的影响.在相同计算水平上采用含时密度泛函理论方法进行了电子光谱研究,讨论了取代基对电子光谱的影响.计算结果表明,标题化合物分子为非平面结构,苯并异硒唑酮环与苯环之间存在一...     

Correlation Study on Sweetness of Amino Acid with Different Configurations and Quantum Chemical Parameters

1 INTRODUCTION Since the introduction of QSAR by Hansch and Fujita in 1964, Deutsch and Hansch have quickly used it in the study of nitrophenylamine sweet reagents. They found good correlation between their distribution coefficients in octanol/water system and sweetness degree. Subsequently, they detected that vibration of aroma-substituent compounds has so- mething to do with sweetness. Henceforth, statistic correlations between structure and sweetness ofseries compounds have been inv…     

Theoretical Study on Electronic and Charge Transfer Properties of Oligo[8]thiophene and Its Circular,Hooped, and Helical Derivatives

The novel linear, circular, hooped, and helical molecules based on oligo[8]thio- phene were theoretically studied for the applications of charge transfer devices. To investigate the influence of topology for oligo[8]thiophene derivatives, the geometry structures, frontier molecular orbital （FMO） energies, charge transport properties, and stability property were predicted by density functional theory methods. The calculated results reported herein show that the oligo[8]thiophene derivative with linear structure has smaller energy gap, and fused oligo[8]thiophene derivative with circular structure has the smallest reorganization energy among the designed molecules. We have also studied the stability properties of the designed molecules, and oligo[8]thiophene derivatives are more stable tharJ the fused oligo[8]thiophene derivatives.     

Controlling the directionality of charge transfer in phthalocyaninato zinc sensitizer for a dye-sensitized solar cell: density functional theory studies

Density functional theory (DFT) calculation on the molecular structures, charge distribution, molecular orbitals, electronic absorption spectra of a series of eight unsymmetrical phthalocyaninato zinc complexes with one peripheral (E)-2-cyano-3-(5-vinylthiophen-2-yl) acrylic acid substituent at 2 or 3 position as an electron-withdrawing group and a different number of electron-donating amino groups at the remaining peripheral positions (9, 10, 16, 17, 23, 24) of the phthalocyanine ring, namely ZnPc-β-A, ZnPc-β-A-I-NH(2), ZnPc-β-A-II-NH(2), ZnPc-β-A-III-NH(2), ZnPc-β-A-I,II-NH(2), ZnPc-β-A-I,III-NH(2), ZnPc-β-A-II,III-NH(2), and ZnPc-β-A-I,II,III-NH(2), reveals the effects of amino groups on the charge transfer properties of these phthalocyanine derivatives with a typical D-π-A electronic structure. The introduction of amino groups was revealed altering of the atomic charge distribution, lifting the frontier molecular orbital level, red-shift of the near-IR bands in the electronic absorption spectra, and finally resulting in enhanced charge transfer directionality for the phthalocyanine compounds. Along with the increase of the peripheral amino groups at the phthalocyanine ring from 0, 2, 4, to 6, the dihedral angle between the phthalocyanine ring and the average plane of the (E)-2-cyano-3-(5-vinylthiophen-2-yl) acrylic acid substituent increases from 0 to 3.3° in an irregular manner. This is in good contrast to the regular and significant change in the charge distribution, destabilization of frontier orbital energies, and red shift of near-IR bands of phthalocyanine compounds along the same order. In addition, comparative studies indicate the smaller effect of incorporating two amino groups onto the 16 and 17 than on 9 and 10 or 23 and 24 peripheral positions of the phthalocyanine ring onto the aforementioned electronic properties, suggesting the least effect on tuning the charge transfer property of the phthalocyanine compound via introducing two electron-donating amino groups onto the 16 and 17 peripheral positions. As expected, compound ZnPc-β-A-I,III-NH(2) with four amino groups at 9, 10, 23, and 24 positions of the phthalocyanine ring shows the best charge transfer directionality among the three phthalocyaninato zinc complexes with four peripheral amino groups.