2-取代芳基菲并咪唑类化合物的电子结构和光谱性质的理论研究

运用密度泛函理论,在B3LYP/6-31G(d)水平上对菲并咪唑(PI)及其8种2-取代芳基衍生物的结构进行了全优化,探讨了取代基对分子结构、电离势(I_P)、电子亲和势(E_A)、电荷转移、前线分子轨道能量和电子吸收光谱等方面的影响.采用含时的度泛函理论(TD-DFT)计算了各分子的气相及液相的电子吸收光谱,计算结果与实验值十分接近.并用GaussSum2.1程序模拟吸收光谱和态密度(DOS)图,结果表明,芳基4′-位上取代基对菲并咪唑(PI)和苯环的骨架结构没有很大的扰动,但它们重新调整了菲并咪唑环和苯环中原子电荷分布,前线分子轨道(LUMO)-HOMO)能隙降低,导致8种取代的化合物的吸收波长均发生了红移.     

第一性原理研究O和S掺杂的石墨相氮化碳(g-C_3N_4)_6量子点电子结构和光吸收性质

利用密度泛函和含时密度泛函理论研究了氧(O)和硫(S)原子掺杂的石墨相氮化碳(g-C_3N_4)_6量子点的几何、电子结构和紫外-可见光吸收性质.结果表明:掺杂后(g-C_3N_4)_6量子点杂质原子周围的C-N键长发生了一定的改变,最高电子占据分子轨道-最低电子未占据分子轨道(HOMO-LUMO)能隙显著减小.形成能的计算表明O原子取代掺杂的(g-C_3N_4)_6量子点体系更稳定,且O原子更易取代N3位点,而S原子更易取代N8位点.模拟的紫外-可见电子吸收光谱表明,O和S原子的掺杂改善了(g-C_3N_4)_6量子点的光吸收,使其吸收范围覆盖了整个可见光区域,甚至扩展到了红外区.而且适当的杂质浓度使(g-C_3N_4)_6量子点光吸收在强度和范围上都得到明显改善.通过O和S掺杂的比较,发现二者在可见光区对(g-C_3N_4)_6量子点的光吸收有相似的影响,然而在长波长区域二者的影响有明显差异.总体而言,O掺杂要优于S掺杂对(g-C_3N_4)_6量子点光吸收的影响.     

桥基取代2,7’-(乙烯基)-二-8-羟基喹啉类化合物的密度泛函理论研究

在B3LYP/6-31G(d)水平上对2,7′-(乙烯基)-二-8-羟基喹啉(2,7′-Ethq_2)及其6种桥基取代物的几何结构进行了全优化,探讨了取代基对分子的结构、电荷转移、前线分子轨道能级、能隙等方面的影响.采用含时的密度泛函理论(TD-DFT)研究各分子的气相及液相中的电子光谱,分析光谱的变化规律.结果表明,取代基的电子效应和立体效应对取代物的电子结构和电子光谱有重要影响,取代基重新调整了2,7′-Ethq_2的原子电荷布居,改变了前线分子轨道能隙,导致吸收光谱发生变化.氨基和氰基对2,7′-Ethq_2影响较为显著,吸收波长红移较大.此外溶剂的极性对其电子光谱也有影响,随溶剂极性的增大,硝基取代物的最大吸收波长发生明显的红移,其它取代物的最大吸收波长均发生较小的蓝移.     

新型含氧亚甲基和亚胺桥键液晶化合物分子结构与光谱的密度泛函理论研究

采用密度泛函理论方法在B3LYP/6-31G*水平上对6个新型含氧亚甲基和亚胺桥键液晶化合物分子的几何结构进行优化计算,讨论了取代基H,CH3,CH3O,C2H5O,NO2,Cl对分子电荷、前线轨道能量和电子吸收光谱等性质的影响.在此基础上使用含时密度泛函理论方法计算了分子第一激发态的电子垂直跃迁能,得到最大吸收波长λmax.计算表明,取代基的引入导致最大吸收波长红移.     

5,7''-(亚甲胺基)-二-8-羟基喹啉及其衍生物的密度泛函理论计算

在B3LYP/6-31G(d)水平上对5,7'-(亚甲胺基)-二-8-羟基喹啉及其5种衍生物进行了几何构型全优化,探讨了喹啉不同位H被吸电子基团CN及羟基O被S原子取代对分子电离势(Ip)、电子亲和势(EA)、电荷转移、前线轨道能量和电子光谱等性质的影响.用含时密度泛函理论(TD-DFT)计算了分子在气相及液相的吸收光谱,计算结果与实验值基本符合.取代基对5,7'-(亚甲胺基)-二-8-羟基喹啉锌分子的性质有较大影响.电子亲和势计算表明,该类化合物的电子亲和势较大,都是较好的电子传输材料.     

掺杂菱形BN片的石墨烯纳米带的电子特性

采用基于密度泛函理论的第一性原理方法,系统研究掺杂菱形BN片的石墨烯纳米带的电子特性.掺杂使扶手椅型石墨烯纳米带（AGNRs）的带隙增大,不同位置掺杂AGNRs的带隙大小略有差异.在无磁性态,无论是否掺杂,锯齿型石墨烯纳米带（ZGNRs）都为金属.在铁磁态,掺杂使ZGNRs由金属转变为半导体.而处于反铁磁态时,无论是否掺杂,ZGNRs都为半导体,掺杂使其带隙发生改变.掺杂的AGNRs和ZGNRs的结构稳定,掺杂ZGNRs的基态为反铁磁态.掺杂菱形BN片可以有效调控GNRs的电子特性.     

经式8-羟基喹啉铝的光谱与激发性质密度泛函

经式8-羟基喹啉铝(mer-Alq3)是一种光电性能优良的小分子有机半导体发光材料.本文采用密度泛函理论(DFT)B3LYP/6-31G*方法和基组对其进行结构优化,计算并研究了该分子的红外光谱、拉曼光谱和前线轨道.计算得到的红外光谱、拉曼光谱均与实验相符.前线轨道表明基态最高占据轨道(HOMO)的电子云主要集中在苯酚环,最低未占据轨道(LUMO)的电子云主要集中在吡啶环.用含时密度泛函理论(TDDFT)计算得到紫外-可见吸收光谱,采用空穴-电子分析法研究了电子激发特征.结果表明:电子从基态到激发态的跃迁,主要是8-羟基喹啉环内或环间的电荷转移,以π-π*跃迁为主,包括局域激发和电荷转移激发两种类型.本工作对mer-Alq3分子发光机理提出更深入的认识,能为进一步提高该分子发光效率和调控分子的发光范围提供一定的理论指导.     

5,7¢-(亚甲胺基)-二-8-羟基喹啉及其衍生物的密度泛函理论计算

在B3LYP/6-31G(d)水平上对5, 7¢-(亚甲胺基)-二-8-羟基喹啉及其5种衍生物进行了几何构型全优化, 探讨了喹啉不同位H被吸电子基团CN及羟基O被S原子取代对分子电离势(IP)、电子亲和势(EA) 、电荷转移、前线轨道能量和电子光谱等性质的影响. 用含时密度泛函理论(TD-DFT)计算了分子在气相及液相的吸收光谱, 计算结果与实验值基本符合. 取代基对5, 7¢-(亚甲胺基)-二-8-羟基喹啉锌分子的性质有较大影响. 电子亲和势计算表明, 该类化合物的电子亲和势较大, 都是较好的电子传输材料.     

BN链掺杂的石墨烯纳米带的电学及磁学特性

基于密度泛函理论第一性原理系统研究了BN链掺杂石墨烯纳米带(GNRs)的电学及磁学特性, 对锯齿型石墨烯纳米带(ZGNRs)分非磁态(NM)、反铁磁态(AFM)及铁磁性(FM)三种情况分别进行考虑. 重点研究了单个BN链掺杂的位置效应. 计算发现: BN链掺杂扶手椅型石墨烯纳米带(AGNRs) 能使带隙增加, 不同位置的掺杂, 能使其成为带隙丰富的半导体. BN链掺杂非磁态ZGNR的不同位置, 其金属性均降低, 并能出现准金属的情况; BN链掺杂反铁磁态ZGNR, 能使其从半导体变为金属或半金属(half-metal), 这取决于掺杂的位置; BN链掺杂铁磁态ZGNR, 其金属性保持不变, 与掺杂位置无关. 这些结果表明: BN链掺杂能有效调控石墨烯纳米带的电子结构, 并形成丰富的电学及磁学特性, 这对于发展各种类型的石墨烯基纳米电子器件有重要意义. 关键词： 石墨烯纳米带 BN链掺杂 输运性质 自旋极化     

咪唑[4, 5-f] 1, 10-邻菲罗啉及其2-取代芳基衍生物的电子结构与光谱性质

分别采用B3LYP/6-31G(d)和CIS/6-31G(d)方法对咪唑[4, 5-f] 1, 10-邻菲罗啉(ip)及其8种2-取代芳基衍生物的基态(S0)和单重激发态(S1)的几何构型进行了全优化, 并采用含时的度泛函理论(TD-DFT)计算了上述化合物的电子吸收和电子发射光谱. 分析了取代基对咪唑[4, 5-f] 1, 10-邻菲罗啉的电子结构、前线分子轨道、电离势Ip、电子亲和势EA及电子光谱的影响. 计算结果表明, 取代基使8种取代衍生物前线分子轨道(LUMO-HOMO)能隙降低,导致其最大吸收和发射波长均发生了红移. 化合物1～8的跃迁类型均为分子内电荷转移（ICT）跃迁,且1～4和5～8的电子转移方向刚好相反. 溶剂对其电子光谱也有影响, 振子强度增大, 最大发射波长红移. 另外, 8种取代衍生物的电离势降低, 电子亲和势增大, 化合物1~4易于空穴的注入, 5~8易于电子的注入.     

金纳米环双体尺寸和耦合效应对表面等离子体共振特性的影响

采用离散偶极子近似方法系统地研究了金纳米环双体的消光光谱及其电场分布. 计算结果表明, 金纳米环双体在耦合作用下的共振消光峰对应着不同振动模式, 改变金纳米环双体的排列方式、 间距和尺寸大小, 其表面等离子体共振消光峰发生红移或蓝移. 因此可以通过对金纳米环双体结构参数和排列方式的设定, 调节其表面等离子体共振消光峰的位置. 电场分布表明, 水平排列的金纳米环双体较单个金纳米环产生更强的局部表面增强电场. 适当的小间距, 较大的内外半径的金纳米环水平阵列更适合做表面增强拉曼散射的衬底, 在生物分子检测等领域具有潜在的应用.     

The role of dipolar interactions for the magnetic properties of ferromagnetic nanoring

We investigate numerically the effects of the dipolar interactions on magnetic properties in small ferromagnetic nanorings using a Monte Carlo technique. Our simulated results show that the strength of dipolar interaction in the magnetic nanoring has an important influence on the magnetization reversal processes and further the coercivity and the remanence. As the dipolar interaction increases, the transition of magnetization reversal processes from the onion-rotation state to the vortex state can occur, which results in an increase in coercivity and a decrease in remanence. On the other hand, it is found that the coercivity and the remanence depend more strongly on the strength of dipolar coupling for the relatively small size nanoring than for the large size nanoring in width. This can be attributed to the stable vortex state without core in smaller width nanoring in contrast to the metastable vortex state with core in larger width nanoring, induced by strong dipolar interactions. Additionally, the temperature dependence of coercivity and remanence in magnetic nanoring is also studied at a fixed dipolar interaction.     

Energetics and structural properties of carbon and oxygen doped hexagonal boron nitride sheets

Energetics and structural properties of carbon and oxygen doped hexagonal boron nitride sheets have been investigated by performing density functional theory calculations. Substitutional doping model has been considered in the neutral charge state. C and O atoms replaced either B or N site in the system as impurities. A systematic study has been performed to see the effect of cell size on the calculated quantities, such as formation energy, relaxation energy, charge and bond length. It has been found that substitution of O atom on the N site in the hexagonal BN sheet is more favorable.     

Effect of doping on electronic properties of double-walled carbon and boron nitride hetero-nanotubes

The effect of boron nitride (BN) doping on electronic properties of armchair double-walled carbon and hetero-nanotubes is studied using ab initio molecular dynamics method. The armchair double-walled hetero-nanotubes are predicted to be semiconductor and their electronic structures depend strongly on the electronic properties of the single-walled carbon nanotube. It is found that electronic structures of BN-doped double-walled hetero-nanotubes are intermediate between those of double-walled boron nitride nanotubes and double-walled carbon and boron nitride hetero-nanotubes. Increasing the amount of doping leads to a stronger intertube interaction and also increases the energy gap.     

Ab initio investigation of oxygen adsorption on the stability of carbon nanotube field effect transistors (CNTFETs)

The influence of oxygen on carbon nanotube field effect transistors (CNTFETs) produced by the charge transfer doping technique, using triethyloxonium hexachloroantimonate ([ (C₂H₅)₃O]⁺[SbCl₆]^?) is reported. Using ab initio density functional theory (DFT), it is suggested that the adsorption of oxygen on the surface of a functionalized carbon nanotube (CNT) could influence both the chemical and electrical stability of this device. Reduced doping is also observed as a consequence of the oxygen adsorption, which could possibly result in a small increase in the Schottky barrier height (SBH) at the metal (source and drain) electrodes.     

Thermal stability and morphological variation of carbon nanorings of different radii during the temperature elevating process: a molecular dynamics simulation study

We study the thermal stability and morphological variations of nanorings with different radii during the temperature elevation using the molecular dynamics (MD) simulation method. Five metastable nanorings were generated using the different initial C–C bond length of armchair carbon nanotubes. The stable structures of the two smallest nanorings have several kinked regions around the nanorings, with the deformations of the inner and outer walls occurring at the same temperature. For the largest three cases, the morphologies of nanorings from the top view display circular shapes at 0 K. For the nanoring with a radius of 146 Å(350 units), the thermal deformation process is very similar to the smallest two cases, but the temperature at which the thermal deformation begins is higher. For the nanoring with nanoring radii of 165 Å (400 units) and 185 Å (450 units), thermal deformation will take place at the inner wall of the nanoring, and then will induce deformation of the outer wall at a higher temperature. Variations of local structures at the kinked regions at different temperatures are also drawn.     

小缺陷铁纳米环的磁特性

用蒙特卡罗方法与快速傅里叶变换微磁学相结合的方法模拟小缺陷铁纳米环的磁化动力学.研究发现小缺陷铁纳米环的磁滞回线出现"双稳态"特征，与实验结果一致.能量研究表明：涡旋态出现的区间为能量局域极小区间.缺陷系统的剩磁随着缺陷位置的变化而变化：剩磁随着Y值的增加先增大后减小，并在中间区域保持相对稳定.系统的自旋组态可以解释上述现象.     

V型噻吩-噁二唑有机共轭分子光电性质的理论研究

使用密度泛函理论在DFT//B3LYP/6-31+G*水平对V型噻吩-噁二唑类7个衍生物分子的电离能,电子亲和势,重组能,吸收光谱进行理论计算.结果表明,7个分子具有较好的平面共轭结构,较高的电子亲和势.从重组能角度看,这些化合物都是较好的电子传输材料.     

Theoretical investigations of the molecular conformation and reorganization energies in the organic diamines as hole‐transporting materials

Recently, organic diamine compounds have been widely used as hole‐transporting materials. In this work, DFT B3LYP method with the 6‐31G^* basis set was performed to investigate the influence of molecular conformation on the reorganization energy of a series of tetra(aryl)benzidine‐based hole‐transport materials. The results indicate that there are two types (i.e., ISB and BD/TPD) of geometric differences of the organic diamines with the relaxation processes. The reorganization energy of the ISB type is lower than that of the BD/TPD type. For the ISB type, the terminal phenyl moiety of the molecular framework plays an important role in determining the Marcus‐type reorganization energy and the central biphenyl moiety does not. A methyl group attached to a terminal phenyl can be used to tune the reorganization energy. According to the statistical analysis, four geometric parameters could affect the reorganization energy of the BD/TPD type. The conformation of either the central biphenyl or the terminal phenyl moiety of the BD/TPD type determines the Marcus‐type reorganization energy associated with the charge transport process at the molecular level. Presumably, this calculation can be employed to predict the electroluminescence (EL) character of the other organic diamines and to improve the design of new hole‐transporting materials in organic light‐emitting devices (OLEDs). Copyright © 2007 John Wiley & Sons, Ltd.     

Energy landscape of fullerene materials: a comparison of boron to boron nitride and carbon

Using the minima hopping global geometry optimization method on the density functional potential energy surface we show that the energy landscape of boron clusters is glasslike. Larger boron clusters have many structures which are lower in energy than the cages. This is in contrast to carbon and boron nitride systems which can be clearly identified as structure seekers. The differences in the potential energy landscape explain why carbon and boron nitride systems are found in nature whereas pure boron fullerenes have not been found. We thus present a methodology which can make predictions on the feasibility of the synthesis of new nanostructures.