石墨烯吸附钛原子的第一性原理研究

基于密度泛函理论研究了单个钛原子分别位于本征石墨烯GR、点缺陷石墨烯（包括空位石墨烯DGR和氮掺杂石墨烯N-GR）薄片表面的吸附机理。通过计算钛原子在本征石墨烯表面不同位置时的吸附结构和吸附能,发现最稳定吸附位置是碳六元环的中心;计算了各个吸附体系的吸附能、态密度和差分电荷密度,研究表明三个吸附体系碳钛间均产生了电子轨道杂化,掺氮后的石墨烯对钛原子的吸附性能略微增强,而空位石墨烯对钛的吸附能是本征石墨烯的4倍,费米能级附近电子态局域化程度最大,吸附效果最好。     

掺杂硅烯吸附CO分子的第一性原理研究

硅烯具有独特的电子、光学、热学、力学以及量子特性,在电子器件、电极材料、储氢材料、催化剂和气体传感器等领域有巨大的潜在应用价值.本文采用基于密度泛函理论的第一性原理计算方法,利用Materials Studio软件中的CASTEP程序包对硅烯与CO分子之间的吸附行为进行了研究.重点研究了硅烯掺杂方式、CO分子吸附构型及硅烯空位缺陷浓度对CO分子吸附的影响,研究结果表明：1)空位缺陷硅烯对CO分子的吸附能力最强;2)碳原子垂直朝向空位缺陷硅烯更有利于CO分子的吸附;3)硅烯对CO分子的吸附能力随其空位浓度的增加显著增强;4)空位硅烯向CO分子转移电荷,电荷转移量与二者的吸附作用强弱呈正相关.该研究可为硅烯基CO气体传感器的设计提供理论指导.     

石墨烯吸附Al2Cl6分子的第一性原理与Monte Carlo研究

采用第一性原理与蒙特卡罗方法研究Al₂Cl₆气体分子在石墨烯表面的吸附性能与光电性质，结果表明：(1)石墨烯对Al₂Cl₆气体分子具有较强的物理吸附作用，两个Al原子的连线与石墨烯平面近乎平行且两个Al原子处于紧靠顶位的桥位位置时最稳定；(2)温度升高不利于Al₂Cl₆气体分子吸附并存在阶跃式降低，气体逸度增加有利于吸附并存在阶跃式升高，Al₂Cl₆气体分子插入石墨/双层石墨烯/多层石墨烯宜将温度维持在AlCl₃沸点附近，并增加气体的压力；(3)Al₂Cl₆的吸附对石墨烯的电子结构进行了调控，但没有明显改变石墨烯费米能级附近的态密度以及“赝能隙”;(4)Al₂Cl₆的吸附对体系光学参数的影响十分明显，静态介电常数提高近5倍，使体系屏蔽效应有较大增强，在长波波段的吸收性能、反射性能及光电导也有了明显提升.     

First-principles studies of graphene antidot lattices on monolayer h-BN substrate

The structures and electronic structures of hetero bilayers composed of graphene antidot lattice (GAL) on monolayer h-BN substrate are studied in first-principles method. Bond lengths, interlayer distances, flatness, biaxial strain effects, and effects of translating the GAL layer are studied and analyzed in detail. Results show that introducing a monolayer BN substrate makes the zero-bandgap $5\times 5$ GAL open a bandgap up to 28 meV, while it makes the semiconducting $6\times 6$ GAL keep its low-energy electronic structure almost intact except a small bandgap change by tens of meV at most. Our studies demonstrate that h-BN is a promising substrate for GAL.     

First-principles study on the structural and electronic properties of graphene upon benzene and naphthalene adsorption

Within the framework of the local density approximation (LDA) of the density functional theory (DFT) and the pseudopotential method, we have carried out ab initio calculations to investigate the structural and electronic properties of graphene upon the adsorption of benzene and naphthalene molecules. Our total-energy calculations suggest that, for both benzene and naphthalene adsorbed on graphene, the stack configuration is the most stable structure. The corresponding adsorption energies at different sites are estimated for both molecular adsorbates. The equilibrium parameters and the electronic band structure for the stable geometries have been calculated and compared with the available findings.     

Y掺杂空位石墨烯对NO及CO气体表面吸附的第一性原理研究

摘　要：基于第一性原理的计算方法,建立了本征石墨烯、空位石墨烯及钇( Y)掺杂空位石墨烯模型,并计算了CO、NO在三类石墨烯表面的吸附过程. 从表面能、吸附结构、吸附能和态密度四个方面进行分析讨论,研究掺杂Y对CO、NO气体吸附性能的影响. 结果表明：CO、NO与本征石墨烯之间的吸附为弱的物理吸附,掺杂Y后增强了材料表面对CO、NO的吸附效果,最大吸附能分别为7.414eV、6.702eV,属于化学吸附;掺杂Y使空位石墨烯费米能级附近有了更多的活跃电子,其吸附NO后体系由半金属转变为金属特性,该特性能为开发更加优良的石墨烯气敏材料提供理论支持.     

A-Z-A型石墨烯场效应晶体管吸附 效应的第一性原理研究

利用第一性原理的计算方法, 研究了A-Z-A型GNR-FET的电子结构和输运性质及其分子吸附效应. 得到了以下结论: 纯净的A-Z-A型GNR-FET具有典型的双极型晶体管特性, 吸附分子的存在会使纳米带能隙变小. 对于吸附H, H₂, H₂O, N₂, NO, NO₂, O₂, CO₂和SO₂分子的情况, A-Z-A型GNR-FET仍然保持着场效应晶体管的基本特征, 但吸附不同类型的分子会使GNR-FET的输运特性发生不同程度的改变; 对于吸附OH分子的情况, 输运特性发生了本质的改变, 完全不具有场效应晶体管的特性. 这些研究结果将有助于石墨烯气体探测器的工程实现, 并对应用于不同环境中GNR-FET的设计具有重要指导意义.     

First-principles studies of Fe atoms adsorption on hydrogen-terminated boron nitride nanoribbons

By using density functional theory (DFT), we have studied the adsorption of Fe atoms on boron nitride nanoribbons (BNNRs). The stabilities of Fe atoms adsorption on BNNRs for the inner sites are very weakly dependent on the adsorption sites and Fe atoms energetically prefer to be adsorbed on the edge boron sites. The analysis of electronic structures shows that the most of the stable systems are the interesting spin gapless semiconductors. The magnetism of the Fe adatom is preserved well on the BNNRs, very close to that of the corresponding isolated atom for all the considered adsorption sites.     

第一性原理分析二氧化碳在CaO(100)表面的吸附性能

运用广义梯度密度泛函理论（GGA-PW91）结合周期平板模型方法,研究了CO2分子分别在1×1×1和2×2×1CaO(100)超晶胞面最稳定位的吸附行为。结果表明：CaO(100)表面的Osurf原子为CO2分子的有效吸附位,能够和CO2分子形成稳定吸附键C-Osurf, 其吸附能为0.858 eV。在吸附前后C和Osurf原子的价电子组态分别由2s0.892p2.47和2s1.842p4.99变化为2s0.682p2.33和2s1.902p5.17,而且在CO2分子中的O2s原子与Surface层的Casub4s原子间存在相互作用。考察了多个CO2分子在2×2×1 CaO(100)表面吸附时存在分子间相互排斥作用,发现当四个CO2分子吸附到2×2×1CaO(100)超晶胞面时,排斥能为1.76 eV,不利于CO2分子的吸附。     

第一性原理分析二氧化碳在CaO(100)表面的吸附性能

运用广义梯度密度泛函理论（GGA-PW91）结合周期平板模型方法,研究了CO2分子分别在1×1×1和2×2×1CaO(100)超晶胞面最稳定位的吸附行为。结果表明：CaO(100)表面的Osurf原子为CO2分子的有效吸附位,能够和CO2分子形成稳定吸附键C-Osurf, 其吸附能为0.858 eV。在吸附前后C和Osurf原子的价电子组态分别由2s0.892p2.47和2s1.842p4.99变化为2s0.682p2.33和2s1.902p5.17,而且在CO2分子中的O2s原子与Surface层的Casub4s原子间存在相互作用。考察了多个CO2分子在2×2×1 CaO(100)表面吸附时存在分子间相互排斥作用,发现当四个CO2分子吸附到2×2×1CaO(100)超晶胞面时,排斥能为1.76 eV,不利于CO2分子的吸附。     

Fe,Co,Ni掺杂石墨烯表面吸附C_2H_4的第一性原理研究

基于密度泛函理论(DFT)的广义梯度近似(GGA),本文对本征石墨烯以及掺杂Fe,Co,Ni石墨烯的几何结构和电子性质进行了优化计算,并计算了C_2H_4在本征石墨烯以及掺杂石墨烯表面的吸附过程,讨论了体系的吸附能、稳定性、DOS及掺杂对键长的影响.结果表明C_2H_4在本征石墨烯B位的吸附和掺杂石墨烯的吸附为化学吸附,在本征石墨烯T和H位的吸附为物理吸附;掺杂后石墨烯的比表面积增大,与本征石墨烯相比,掺杂使费米能级附近的态密度积分显著提高,表明掺杂石墨烯的电导性会发生变化,从而影响对C_2H_4的气敏度..C_2H_4在Fe、Co、Ni分别掺石墨烯的最佳吸附位为T位、H位和B位;掺杂Fe,Ni后体系的吸附能力显著提高,且掺杂Ni时体系的吸附能力最好.     

First-principles studies of H2S adsorption and dissociation on metal surfaces

Density functional theory calculations were employed to investigate the molecular and dissociative adsorption of H₂S on the closed packed surfaces of a number of important noble metals (Ag(1 1 1), Au(1 1 1) and Cu(1 1 1)) and transition metals (Ir(1 1 1), Ni(1 1 1), Pd(1 1 1) and Pt(1 1 1)). Energy minima corresponding to adsorbed states were identified with H₂S binding preferentially at the top sites. The adsorption of other S moieties (SH and S) was also examined. SH and S were found to prefer bridge sites and hollow sites, respectively. The binding of H₂S and its S-containing dissociated species is stronger on the transition metals. The elementary reactions of abstraction of H from H₂S to form a surface SH intermediate and abstraction of H from SH to form a surface S intermediate as model pathways for the dissociation of H₂S were examined. Our results suggest that H₂S decomposition on the aforementioned transition metal surfaces is more facile, both thermodynamically and kinetically.     

Theoretical studies of hydrogen molecule adsorption on flat and stepped platinum surfaces

Theoretical calculations have been applied to the adsorption of hydrogen molecule on flat and stepped platinum surfaces. The method of large unit cell is modified to deal with the stepped surface as well as the flat one. This method is free from the boundary effect which is inevitable in the cluster method. The results calculated for the d-band width and the highest occupied level are in good agreement with the experiments. For the dissociative adsorption, the bottom of the step site is the most favorable, and the result is attributed to the extra orbital interactions at this site.     

First-principles studies on the adsorption of molecular oxygen on Ba(110) surface

The adsorption of O₂ on Ba(110) surface is studied with first-principles calculations based on density functional theory. Our calculations predict that O₂ may prefer to dissociative adsorption on Ba(110) surface without obvious barrier. Also our results do not support the model of charge transfer from the surface to the molecule as a bond breaking mechanism. Instead, the increasing hybridization between O₂ orbitals and the d states of Ba(110) surface may play an important role in the dissociation adsorption.     

Modification of the structural and electronic properties of graphene by the benzene molecule adsorption

A survey of the literature data on the adsorption of benzene on graphene or carbon nanotubes indicates that the distance between the graphene sheet and benzene molecule is determined from weak van der Waals forces (∼3.40 Å). In our theoretical study, it was found that the benzene/graphene structure (in a specific configuration with carbon atoms located at the atop positions, stacked directly on the top of each other) forms strong covalent bonds, if the distance between the graphene and benzene is about 1.60 Å. Such a short distance corresponds to about a half of the usual separation between the graphite layers. It was also shown that at such a short distance the carbon atoms of the benzene molecule move towards the graphene sheet, whereas the hydrogen atoms move in a different direction, thus breaking the benzene planar structure.     

DNA adsorption on graphene

We study analytically the properties of the optical absorption and the spatial weak-light solitons in a quantum dot molecule system with the interdot tunneling coupling (ITC). It is shown that, for the linear case, there exists tunneling induced transparency (TIT) in the context of a weak ITC, while the TIT can be replaced by Autler-Townes splitting in the presence of a strong ITC. For the nonlinear case, it is probable to realize the spatial optical solitons even under weak light intensity. Interestingly, we find that there appears transformation behavior between the bright and dark solitons by properly turning both the ITC strength and the detuning of the probe field. Meanwhile, the transformation condition of the bright and dark solitons is obtained. Additionally it is also found that the amplitude of the solitons first descends and then rises with the increasing of ITC strength. Our results may have potential applications for nonlinear optical experiments and optical telecommunication engineering in solid systems.     

本征及掺杂磷烯对2,3,7,8-TCDD吸附机理的计算模拟研究

2,3,7,8-四氯二苯并对二噁英(2,3,7,8-TCDD)是二噁英家族中危害人类和环境最显著的一种.设计一种高效,灵敏的吸附剂来检测和去除2,3,7,8-TCDD对人类和环境的影响是亟需解决的问题.本研究利用基于密度泛函理论(DFT)的计算模拟方法探索了本征磷烯对2,3,7,8-TCDD的吸附机理,并详细考察了掺杂Ti, Fe, Ca, Al金属原子后磷烯对2,3,7,8-TCDD吸附的影响.研究结果表明2,3,7,8-TCDD初始构型会影响磷烯对其吸附,当平躺于磷烯表面时有较大的吸附.而且掺杂金属原子的磷烯对2,3,7,8-TCDD的吸附也存在较大的影响,掺杂金属原子均增大了磷烯对2,3,7,8-TCDD的吸附,其中Ca掺杂磷烯>Fe掺杂磷烯>Ti掺杂磷烯>Al掺杂磷烯.研究结论对于2,3,7,8-TCDD的处理带来了新的思考方向,有望为二噁英的检测和去除提供有用的理论指导.