有机分子二苯乙烯系列衍生物第一超极化率的理论研究

采用耦合-微扰Hartree-Fock方法(CPHF),计算了二苯乙烯系列衍生物的静态第一超极化率.研究发现,具有离域的共轭体系和电子推拉对结构的分子,有利于发生分子内电荷转移,因而具有大的第一超极化率.进一步研究体系中取代基的位置,给体与受体的数量和得失电子的能力,分子的共面性和对称性对分子第一超极化率的影响,结果表明,有机分子拥有更多数量与更强得失电子能力的给体和受体,最高占据分子轨道(HOMO)和最低未占据分子轨道(LUMO)空间分布的不对称,具有较高的原子共面性和较低的分子中心对称性,都能显著增加 关键词： 二苯乙烯 非线性光学 第一超极化率 空间效应     

Nonadiabatic dynamics of electron injection into organic molecules

We numerically investigate the injection process of electrons from metal electrodes to one-dimensional organic molecules by combining the extended Su-Schrieffer-Heeger (SSH) model with a nonadiabatic dynamics method. It is found that a match between the Fermi level of electrodes and the highest occupied molecular orbital (HOMO) or the lowest unoccupied molecular orbital (LUMO) of organic molecules can be greatly affected by the length of the organic chains, which has a great impact on electron injection. The correlation between oligomers and electrodes is found to open more efficient channels for electron injection as compared with that in polymer/electrode structures. For oligomer/electrode structures, we show that the Schottky barrier essentially does not affect the electron injection as the electrode work function is smaller than a critical value. This means that the Schottky barrier is pinned for a small work-function electrode. For polymer/electrode structures, we find that it is possible for the Fermi level of electrodes to be pinned to the polaronic level. The condition under which the Fermi level of electrodes exceeds the polaronic level of polymers is shown to not always lead to spontaneous electron transfer from electrodes to polymers.     

Tuning HOMO–LUMO levels: trends leading to the design of 9‐fluorenone scaffolds with predictable electronic and optoelectronic properties

Highest occupied molecular orbital–lowest unoccupied molecular orbital (HOMO–LUMO) tuning is an important consideration in the development of organic‐based semiconducting materials. A study of the specific effects and overall trends for the HOMO–LUMO tuning of a diverse series of 9‐fluorenones by means of extended conjugation and substituent effects is described. Trends were explored in a range of compounds, beginning with structures having highly electron‐withdrawing substituents and progressing to structures having highly electron‐donating substituents. Compounds with an incremental increase in conjugation were also examined. Electrochemical and optical measurements were used to calculate the HOMO–LUMO levels and HOMO–LUMO bandgap (HLG) for each structure. Results from both methods were compared and correlated with the differences in molecular structure. Increasing the electron‐donating character of the substituents was observed to decrease the HLG and increase the energy levels of the HOMO and the LUMO, whereas an increase in the electron‐withdrawing character produced the opposite results. Increasing conjugation decreased the HLG, increased the HOMO energy level, but decreased the LUMO energy level. Spectroscopic evidence of substituent influence on the carbonyl suggests that substituents directly impact the HLG by influencing the availability of nonbonding electrons within the carbonyl, which impacts the probability of an nπ* transition. The data presented not only elaborate on the HOMO–LUMO tuning of 9‐fluorenone systems but also enable the consideration of 9‐fluorenones as analogous models for HOMO–LUMO tuning in other more complex polyaromatic systems such as bifluorenylidenes. These trends may provide insight into developing materials with specifically tuned HLGs and HOMO–LUMO levels for a variety of applications. Copyright © 2011 John Wiley & Sons, Ltd.     

Structural and electronic properties of supramolecular C60:RU(II)(bipy)3:C60 triad: Ab initio van der Waals calculations

We have investigated the influence of non-local dispersion interactions and temperature on the structure and electronic properties of Ru(bipy)₃-(C₆₀)₂ triad using the ab initio van der Waals density functional (vdW-DF) calculations. It was found that non-local dispersion interactions affects slightly on the structural geometry and charge transfer property of the system under study. Therefore, it's not necessary to consider dispersion interactions which are computationally more expensive than the conventional DFT calculations for the presented supramolecules.The obtained results from the ab initio MD simulations indicated that structural property of respected molecule varies at various temperatures. The Mulliken charge analyses show a remarkable charge transfer about 0.64 electrons between Ru (bipy)₃-bridges as donors and fullerenes as acceptors entities in the isolated molecule by increasing the temperature, the charge transfer was also increased.Our first-principles results for the isolated complex showed that the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) states were located on the fullerene spheroid and thus the charge separation (orbital localization) is not desirable. However, increasing of temperature causes the LUMO's to localize on the acceptor moieties (fullerenes) and the HOMO's on the donor moieties (Ru(bipy)₃). From the results obtained for the molecular orbitals we found that the best distribution is occurred at ambient condition (300 K).     

A density functional theory investigation of the stability,aromaticity, and photophysical behavior for the highly conjugated macrocycles containing 4 pyrroles

Porphyrin ( Pr ), porphycene ( Pc ), and [22]porphyrin(2.2.2.2) ( P[22] ) have been theoretically investigated. We design 2 highly conjugated macrocycles containing 4 pyrroles with different linkage bridges, which are named for 4 pyrrole ( Pf ) and methylene‐dipyrrolidine ( Pm ), as the theoretical model so as to investigate the stability, aromaticity, and photophysical behavior of these porphyrin derivatives, and the influence of getting or losing electron to the neutral molecule. The geometric structures of the molecules are optimized by density functional theory method. The absorptions are calculated by the time‐dependent density functional theory method. Based on the optimized structures, the nucleus‐independent chemical shifts (NICS) are calculated. The molecule with negative NICS value possesses larger highest occupied molecular orbital (HOMO)‐lowest occupied molecular orbital (LUMO) gap than that with positive NICS value, the molecule with bigger positive NICS value possesses smaller HOMO‐LUMO gap, and the molecule with bigger negative NICS value (in absolute value) possesses bigger HOMO‐LUMO gap. The current density indicates that the π‐electron delocalization is more effective in Pr and Pc than in Pf , Pm , and P[22] and corresponds to the stability of molecules. The absorptions of the molecules are all in the UV‐visible and infrared regions. The major transitions for most of the molecules are all from HOMO to LUMO. Compared with Pf ^2? , Pr ^2? , Pc ^2? , and P[22] ^2? , Pm ^2? shows distinctive photophysical properties, which is due to the reduced HOMO‐LUMO gap, structural distortion, and strong antiaromaticity.     

Enhanced charge transfer in a monolayer of the organic charge transfer complex TTF-TNAP on Au(111)

Electronic doping is a key concept for tuning the properties of organic materials. In bulk structures, the charge transfer between donor and acceptor is mainly given by the respective ionization potential and electron affinity. In contrast, monolayers of charge transfer complexes in contact with a metal are affected by an intriguing interplay of hybridization and screening at the metallic interface, determining the resulting charge state. Using scanning tunneling microscopy and spectroscopy, we characterize the electronic properties of the organic acceptor molecule 11,11,12,12-tetracyanonaptho-2,6-quinodimethane (TNAP) adsorbed on a Au(111) surface. The ordered islands remain in a weakly physisorbed state with no charge transfer interaction with the substrate. When the electron donor tetrathiafulvalene (TTF) is added, ordered arrays of alternating TNAP and TTF rows are assembled. In these structures, we find the lowest unoccupied molecular orbital (LUMO) of the free TNAP molecule shifted well below the Fermi level of the substrate. The TNAP is thus charged with more than one electron.     

Electrical Conductivity in Polyazomethines: A Novel Mechanism Derived from All Valence MO Calculation and IR Study of Polymer–Dopant Interaction

A simple mechanism is proposed to explain the variation of electrical conductivity in polyazomethines. The results of semiempirical, all valence, molecular orbital calculations obtained from the PM3 method have been employed to arrive at the mechanism. The difference of energy (ΔE) between highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) alone could not explain the variation in electrical conductivity; however, ΔE together with the LUMO electron density at the atoms that lie on the continuous chain could account for the electrical conductivity in these polymers. The LUMO electron density on these centers may be visualized as the carrier movement. In certain polymers there are intrinsic holes in HOMO. The movement of these intrinsic holes also adds to the electrical conduction. The polyazomethines are prepared by the condensation of diamines with azo bis-aldehydes. A few of these polymers were doped with silver nanoparticles. Many of the doped polymers showed substantial enhancement in conductivity. Strong polymer–dopant interaction, identified by IR spectroscopy, is proposed to be responsible for the increase in conductivity.     

Dynamics of self-localized excitations in a polyacene chain

Dynamical formation processes of self-localized excitations induced by charge injection or photoexcitations in a polyacene chain are investigated by a nonadiabatic dynamic method. The polyacene chain is treated as two alternatively coupled polyacetylene chains. The initial lattice configuration is taken as the pristine polyacene chain. It contains an interchain-coupled neutral soliton as a consequence of odd-number sites in each of the two chains. The nonadiabatic dynamical processes are carefully investigated in the following physical cases: (1) electron injection; (2) electron transition from the highest occupied molecular orbital (HOMO) to the lowest unoccupied molecular orbital (LUMO); (3) electron transition from HOMO to the localized soliton level, and (4) electron-hole pair excited at the continuum absorbtion edge for light polarized parallel to the chain. It is interestingly found that the centers of the electron and the hole excited by light polarized parallel to the chain are separated. Therefore, the photogenerated charge carriers should be favorable in polyacene, which is remarkably different from those found in a single polyacetylene chain.     

碳掺杂硼氮纳米管电子场发射的第一性原理研究

对闭口硼氮纳米管（BNNT）顶层掺碳体系,运用第一性原理研究了电子场发射性能.结果表明,掺碳的BNNT体系电子结构变化显著;外电场愈强,体系态密度向低能端移动幅度愈大,且最高占据分子轨道（HOMO）/最低未占据分子轨道（LUMO）能隙愈小.体系态密度和局域态密度,HOMO和LUMO及其能隙分析一致表明,各种碳掺杂体系中C_eqBNNT的场发射性能最佳. 关键词： 硼氮纳米管 碳掺杂 第一性原理     

Theoretical investigation on the oligothienoacenes under the influence of external electric field

Theoretical investigation on a series of oligothienoacenes has been carried out at the B3LYP/6-31G* level by considering the influence of the external electric field. With the electric field increasing, the carbon-carbon single bonds become shorter and the carbon-carbon double bonds become longer, resulting in a better conjugation. Due to the different electron density, the charge mobility of the sulfur is more obvious than that of the carbon. The highest occupied molecular orbital (HOMO)-lowest unoccupied molecular orbital (LUMO) gap decreases with the EF intensity increasing. The applied EF also changes the spatial distribution of the molecular orbits: LUMO and several higher orbitals shift to the high potential side, whereas HOMO and several lower ones shift to the low potential side. All these features behave more pronounced with increasing conjugated chain length.     

Studies of Luminescence Performance on Carbazole Donor and Quinoline Acceptor Based Conjugated Polymer

We report on the synthesis of conjugated polymer (CV-QP) containing carbazole (donor) and quinoline (acceptor) using Wittig methodology. The structural, optical and thermal properties of the polymer were investigated by FT-IR, NMR, GPC, UV, PL, cyclic voltammetry, atomic force microscopy (AFM) and thermogravimetric analysis (TGA). The polymer exhibits thermal stability upto 200 °C and shows good solubility in common organic solvents. The polymer has optical absorption band in a thin film at 360 nm and emission band formed at 473 nm. The optical energy band gap was found to be 2.69 eV as calculated from the onset absorption edge. Fluorescence quenching of the polymer CV-QP was found by using DMA (electron donor) and DMTP (electron acceptor). AFM image indicated that triangular shaped particles were observed and the particle size was found as 1.1 μm. The electrochemical studies of CV-QP reveal that, the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) energy levels of the CV-QP are 6.35 and 3.70 eV, which indicated that the polymers are expected to provide charge transporting properties for the development of polymer light-emitting diodes (PLEDs).     

TPD/PBD界面电致激基复合物几何结构和 电子结构的理论

利用第一性原理对由TPD⁺和PBD^-形成的电致激基复合物(TPD⁺PBD^-)进行基于密度泛函的能量、轨道等性质的计算。结果表明:界面处离子态的TPD⁺ 和 PBD^-更易形成处于更低能量状态的电致激基复合物。几何结构的数据分析表明:电致激基复合物(TPD⁺PBD^-)是电子从PBD^-转移至TPD⁺形成的电荷转移态;电致激基复合物的最低空轨道(LUMO)定域在电致激基复合物PBD^- 的一侧;它的最高占据轨道(HOMO)定域在电致激基复合物TPD⁺的一侧;且前线分子轨道无重叠。电致激基复合物的能隙为1.3 eV,与PBD 的LUMO到TPD的HOMO的能级差1.6 eV相近。在理论上说明了电致激基复合物的发光是从PBD的LUMO到TPD的HOMO的电子跃迁。     

Electronic structure and molecular orbital study of hole-transport material triphenylamine derivatives

Recently, triphenylamine (TPA), 4,4′-bis(phenyl-m-tolylamino)biphenyl (TPD), 4,4′-bis(1-naphthylphenylamino)biphenyl (NPB) and their derivatives are widely used in the organic light-emitting diode (OLED) devices as a hole-transporting material (HTM) layer. We have optimized twenty different structures of HTM materials by using density functional theory (DFT), B3LYP/6-31G method. All these different structures contain mono-amine and diamine TPA derivatives. The energies of highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) along with molecular orbitals for these HTMs are also determined. We have found that the central amine nitrogen atom and the phenyl ring, which is next to the central amine nitrogen atom, show significant contribution to the HOMO and LUMO, respectively. The sum of the calculated bond angles (α+β+γ) of the central amine nitrogen atom has been applied to describe the bonding and the energy difference for HOMO and LUMO in these TPA derivatives. Electronic structure calculations have been performed for these TPA derivatives. Again, the LCAO-MO patterns of HOMO and LUMO levels of these derivatives are used to investigate their electron density. A series of electron-transporting steps are predicted for these compounds employing these calculated results.     

红景天苷分子结构与光谱的密度泛函理论分析

随着科学技术不断发展，中药质量控制和质量评价出现了越来越多的新技术。在中药标准化过程中，现代药学研究已经取得了许多令人瞩目的成果，检测方法和技术取得了很大的进展，由过去单一指标检测发展到多指标检测，但由于中草药成分复杂，作用机制不明等因素制约了中药的发展。红景天是一种少数民族药，是中医药发展不可或缺的组成部分。红景天苷是红景天中的主要有效成分之一，其提取、分离和纯化等方法报道甚多，但其分子键长键角二面角、前线轨道分布、表面静电势等分子参数却鲜有报道，这些都是决定其化学性质和反应机理的重要因素。采用Gaussian09W化学计算软件的密度泛函理论DFT/B3LYP方法和6-31(d)基组优化红景天苷分子，得到其稳定结构的键长、键角和二面角参数。在此稳定构型的基础上，计算其表面静电势（ESP）、最低空轨道（LUMO）、最高占据轨道（HOMO）、红外光谱（IR）和核磁共振波谱数据（NMR）。分别对IR和NMR峰位置进行了归属并与文献报道数据进行了对比，结果表明：计算结果的红外吸收频率没有出现虚频说明该优化结果是合理可靠的，最高占据轨道能量E=-5.82 eV，最低空轨道能量E=-0.000 42 eV，二者差值为5.81 eV。通过绘制了轨道的电子云分布图可以看出HOMO轨道主要分布于苯环，为π电子的成键轨道有一个节面；LUMO轨道也主要分布在苯环上，为π电子的反键轨道有两个节面。表面静电势的绘制可以直观地反映出分子中哪部分易发生亲核取代、哪部分易发生亲电取代反应。通过绘制第一激发态和基态电子差值，可以直观地得到电子的迁移方向。对红景天苷分子计算理论研究可以为进一步探索其化学反应机理、结构修饰和活性位点的确认等提供重要的参考依据和新思路。     

First-principles study of electronic properties of interfacial atoms in metal-metal contact electrification

The mechanism of contact electrification between metals was studied using the first-principles method, taking the Ag-Fe contact as an example. Charge population, charge density difference, the orbitals and densities of states (DOS) were calculated to study the electronic properties of the contacting interfacial atoms. Based on the calculation, the amount of contact charge was obtained. The investigation revealed that the electrons near Fermi levels with higher energies transfer between the outermost orbitals (s orbitals for Ag and d orbitals for Fe). Meanwhile, polarized covalent bonds form between the d electrons in the deep energy states. These two effects together lead to an increase of charge magnitude at the interface. Also, the electrons responsible for electrification can be determined by their energies and orbitals.     

DFT study of dihydrogen interactions with lithium containing organic complexes C4H4-mLim and C5H5-mLim （m = 1, 2）

The interactions of dihydrogen with lithium containing organic complexes C₄H_4-mLi_m and C₅H_5-mLi_m (m = 1, 2) were studied by means of density functional theory (DFT) calculation. For all the complexes considered, each bonded lithium atom can adsorb up to five H₂ molecules with the mean binding energy of 0.59 eV/H₂ molecule. The interactions can be attributed to the charge transfer from the H₂ bonding orbitals to the Li 2s orbitals. The kinetic stability of these hydrogen-covered organolithium molecules is discussed in terms of the energy gap between the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO). The results indicate that these organiclithium structures can perhaps be used as building units for potential hydrogen storage materials.     

Electronic structure of the molecular switch tetra-<Emphasis Type="Italic">tert</Emphasis>-butyl-azobenzene adsorbed on Ag(111)

Occupied and unoccupied electronic states in tetra-tert-butyl-azobenzene (TBA) absorbed on Ag(111) have been investigated by one-photon and two-photon photoemission spectroscopy. These measurements allow the quantitative determination of energetic positions of the highest occupied (HOMO) and the lowest unoccupied molecular orbital (LUMO) as well as the n=1 image potential state. The assignment of the electronic states are supported by quantum chemical calculations. Experimentally a HOMO–LUMO gap of 2.85 eV is observed, whereas the gap obtained from the calculated molecular orbital energies is 0.92 eV larger. This discrepancy can be explained by image charge screening. Furthermore, two unoccupied final states located 0.18 and 0.43 eV above the vacuum level, respectively, have been identified. PACS 73.20.-r; 74.25.Jb; 79.60.-i; 79.60.Dp; 68.43.Vx     

DFT and ab initio study on non-linear optical (NLO) properties of some organic complexes with different conjugate linker and substituent groups

A series of Schiff-bases chromophores containing imine or double C=C bond linkers between the donor and acceptor have been studied by first-principles calculations. The molecular structures, electronic properties and second order nonlinearities were investigated by DFT and ab initio methods. The optimized structural parameters of these Schiff-base derivates showed that these compounds are stable. The results of TD-DFT calculations indicate that the derivatives with the heterocyclic and imine linker have a red shift absorption compared to derivatives with the double C=C or N=N bonds. The analysis of the frontier molecular orbitals indicates that the CN group and the heterocycle linked by the CN or imine group has contribution to the LUMO orbital while the groups N(CH₃)₂ and the benzene ring linked by the double C=C or N=N bond have contribution to the HOMO orbital. The CN and the heterocyclic acceptors enable the derivatives to have a larger first static hyperpolarizability. However, the compounds 3-{4-[(4-Dimethylamino-phenylimino)-methyl]-pyridin-1-yl}-propanel-1-sulfonoperoxoic acid and 3-{4-[(4-Dimethylamino-phenylimino)-methyl]-quinolin-1-yl}propanel-1-sulfonoperoxoic acid with a substituent also have large first static hyperpolarizabilities due to the overwhelming contributions of electron density of the group to the HOMO orbital, that is, the HOMO orbital were constituted by the SO ₃ ^? group only. In order to understand the influence of the energy gap (??E) between the HOMO and the LUMO orbitals on the first static hyperpolarizability, we calculated the energy gap (??E) of all Schiff-base compounds. The results show that the smaller the HOMO-LUMO energy gap the larger the first static hyperpolarizability. The present study demonstrated that these compounds which have pure C=N double bond and heterocyclic substitution groups may have potential applications in the development of NLO materials.     

Self-consistent theory for the built-in voltage in metal–organic semiconductor–metal structures

A self-consistent theory for calculation of built-in voltage (U_bi) of metal–organic semiconductor–metal (MOSM) structures is developed based on Gaussian energy distribution of highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO). It is shown that the built-in voltage depends not only on the work function difference of the two electrodes, but also on the mean energy level of HOMO and LUMO, as well as the Gaussian width of the energy distribution. The theory predicts that the spreading of HOMO and LUMO levels will results in an increase of U_bi, and that U_bi decreases with increasing temperature.     

First-principles calculation of contact electrification and validation by experiment

Contact electrification is one of the most well-known phenomena in physics and examples arise in almost every industry. However, a scientific basis for contact charging remains unknown. Here, we present a theoretical study of contact electrification, supported by experiments, to calculate for the first time charge transfer between material surfaces from first principles physics. Electronic structure calculations and experiments are performed on single-crystal alumina (sapphire) and silicon oxide (quartz) surfaces, which have well-ordered structures that enable rigorous modeling. Both experiments and calculations show that sapphire charges positively and quartz charges negatively. The calculations cannot determine the magnitude of charge densities remaining on separated surfaces from first principles, as these are non-equilibrium effects, but our analysis is consistent with experimentally obtained charge densities of 10 μC/m². These results indicate the possibility of quantitatively predicting and explaining contact electrification from only the molecular structure of material surfaces.