掺硼水吸附碳纳米管电子场发射性能的第一性原理研究

运用第一性原理研究了掺硼碳纳米管(BCNT)顶端吸附水分子后的电子场发射性能.结果表明：掺B及吸附H₂O的碳纳米管(BCNT+H₂O)端部形成电子聚集的原子尺度微区,其电子态密度(DOS)在费米能级(E_f)附近有很大提高.根据计算的电子DOS,HOMO/LUMO及Mulliken电荷分布等可知BCNT+H₂O比CNT+H₂O有更好的场发射性能. 关键词： 掺硼碳纳米管 吸附 密度泛函理论 电子场发射     

金原子掺杂的碳纳米管吸附CO气体的密度泛函理论研究

鉴于碳纳米管复合材料具有较强气敏性,该性质对于指导剧毒气体探测器的研发具有重要意义,因此,本文采用密度泛函方法对CO气体在本征、金原子掺杂(8,0)单壁碳纳米管的吸附行为进行研究. 通过对吸附体系的几何、电子结构研究表明,CO分子在金原子掺杂的碳纳米管外壁的金原子位置处的吸附能力远大于CO在本征碳纳米管处的吸附,此外,还计算了两种典型位置的电子密度、态密度,进一步支持了掺金碳纳米管对CO气体具有超强的敏感性,因此,金原子掺杂的碳纳米管有望成为探测CO气体的新一代气敏元件. 关键词： 碳纳米管 CO 金原子 掺杂     

Au掺杂CNT吸附NO的第一性原理研究

碳纳米管(CNT)对于气体有超强的敏感性,可用于制备基于CNT的有害气体传感器.本文采用基于密度泛函理论的第一性原理研究Au掺杂CNT对NO和O_2的吸附特性.对吸附能、最终吸附距离、电荷转移量、态密度等的分析显示,Au掺杂使得CNT与NO间的交互作用明显增强,其中N原子端靠近CNT交互作用更强.禁带宽度和电荷密度分析表明,相比于NO分子中O原子端或者O2吸附,NO分子中N原子端与CNT发生交互作用会使体系导电性变化更为明显.说明Au掺杂能够很好地屏蔽空气中O_2对CNT导电性的影响,Au掺杂CNT作为NO气敏材料是可行的.     

Al和N共掺p型Zn1-xMgxO电子结构的第一性原理计算

采用密度泛函理论下的第一性原理平面波超软赝势方法,对Zn1-xMgxO超晶胞和掺杂Al,N后的Zn1-xMgxO超晶胞分别进行了优化计算.结合广义梯度近似计算了Al和N共掺杂后Zn1-xMgxO的能带结构、电子态密度和Mulliken电荷布居分布.计算表明:掺入N原子的2p态电子为Zn1-xMgxO价带顶提供空穴载流子,使Zn1-xMgxO价带顶向高能方向移动;掺入Al原子的3p态电子则与N原子的2p态电子在费米能级附近发生轨道杂化,使费米能级处价带能级展宽,Al和N共掺杂可获得p型Zn1-xMgxO.     

氮掺杂及水分子吸附碳纳米管电子场发射第一性原理研究

对闭口碳纳米管(CNT)顶端分层掺氮及吸附不同数目水分子体系,运用第一性原理研究了有电场存在时的电子场发射性能.结果表明：掺氮并吸附水分子的CNT结构稳定;外电场愈强、水分子数愈多,体系态密度(DOS)向低能端移动幅度愈大且最高分子占据轨道(HOMO)/最低分子空轨道(LUMO)能隙愈小.吸附能,DOS/LDOS,HOMO/LUMO及其能隙分析一致表明,第三层氮掺杂CNT吸附不同数目水分子体系的场发射性能最佳. 关键词： 氮掺杂 水吸附 密度泛函理论 电子场发射     

B12-nAlnN12 (n=0, 6, 12) 的稳定性和电子结构研究

通过Al取代B在B12N12中掺杂,基于密度泛函理论对B6Al6N12的稳定性进行了系统研究．表明在B6Al6N12中,Al和B倾向于相对分开．在最稳定结构中,B原子和Al原子分别处在笼的两半．我们还分析了B12-nAlnN12 (n=0, 6, 12)的电子结构,B12N12的能隙为6.84eV,掺Al后其能隙明显变窄,Al12N12和B6Al6N12的能隙分别为3.91eV和4.08eV．NBO分析表明,B12N12中B/N原子的电荷分别为±1.17,Al12N12中Al/N 原子的电荷分别为±1.85．在B6Al6N12中,B/Al原子上的电荷分别为1.06~1.12和1.86~1.91,N原子上的电荷为-1.18~-1.83．     

B12-nAlnN12 (n=0, 6, 12) 的稳定性和电子结构研究

通过Al取代B在B12N12中掺杂,基于密度泛函理论对B6Al6N12的稳定性进行了系统研究．表明在B6Al6N12中,Al和B倾向于相对分开．在最稳定结构中,B原子和Al原子分别处在笼的两半．我们还分析了B12-nAlnN12 (n=0, 6, 12)的电子结构,B12N12的能隙为6.84eV,掺Al后其能隙明显变窄,Al12N12和B6Al6N12的能隙分别为3.91eV和4.08eV．NBO分析表明,B12N12中B/N原子的电荷分别为±1.17,Al12N12中Al/N 原子的电荷分别为±1.85．在B6Al6N12中,B/Al原子上的电荷分别为1.06~1.12和1.86~1.91,N原子上的电荷为-1.18~-1.83．     

Al、N共掺杂实现p-型ZnS的第一性原理研究

 采用基于密度泛函理论的第一性原理平面波超软赝势方法,计算了闪锌矿ZnS、N掺杂以及Al、N共掺杂ZnS晶体的电子结构,分析了N掺杂以及Al和N共掺杂ZnS晶体的能带结构、电子态密度以及Mulliken电荷分布。计算结果表明：N掺杂ZnS在能带中引入了深受主能级,N原子的2p态在价带顶提供了空穴载流子,载流子局域于价带顶附近;Al和N共掺使得受主能级变宽,非局域化特征明显,提高了掺杂浓度和系统的稳定性,更加有利于获得p-型ZnS。     

石墨烯及其掺杂量子点的荧光性能研究

采用基于密度泛函理论(DFT)的平面波超软赝势法,研究了石墨烯量子点的本征结构、边缘位置掺B、中间位置掺B、边缘位置掺N、中间位置掺N五种结构的电子结构和光学性质.结果表明,石墨烯量子点的激发能吸收主体是基质,杂质原子的掺入会导致禁带宽度变窄,费米能级升高,发射光谱红移,其中给电子体杂质会导致LUMO能级和HOMO能级升高,受电子体杂质会导致LUMO能级升高,HOMO能级降低.中间位置掺杂相对于边缘位置掺杂红移更明显.     

Rh在单壁碳纳米管上吸附的密度泛函理论研究

本文利用密度泛函理论研究了Rh原子在（6,6）单壁碳纳米管内外的吸附行为. 通过对Rh在单壁碳纳米管上不同吸附位的吸附构型与吸附能的研究发现: Rh吸附在管内、外的洞位最稳定, 且管外吸附比在管内强. 这是由于单壁碳纳米管的卷曲效应使得管外电荷密度比管内大造成的. 态密度分析表明, 吸附在管内外的Rh原子的5s电子均转移到了4d轨道上; Rh原子4d轨道上的电子转移到了（6, 6）碳管上, 使Rh带正电, 碳管带负电. 结合能带分析表明, Rh原子吸附在管内磁性较弱, 而吸附在管外较强. 关键词： 密度泛函理论 单壁碳纳米管 Rh原子 吸附     

Enhanced interface interaction between modified carbon nanotubes and magnesium matrix

Carbon nanotube (CNT)/metal interface interaction is critical to the mechanical properties of CNT-reinforced metal matrix composites (MMCs). In this paper, in order to realize the chemical modification of the interface interaction between CNTs and Mg matrix, different types of defects (monovacancy, carbon and oxygen adatoms, as well as p-type boron and n-type nitrogen substitution) are introduced in CNTs to investigate the effect of the defects on the interface interaction (E_ib) between CNT and Mg (0 0 0 1) surface. Moreover, two models (adsorption model and interface model) are compared and validated to investigate the interface interaction. It is revealed that the CNT with the carbon adatom has the highest E_ib with the Mg (0 0 0 1), and the effect of boron doping on E_ib is superior to the intermediate oxygen which has already been proved experimentally in the enhancement of the interface interaction in MMCs. In terms of the electronic structure analysis, we reveal the micro-mechanism of the increase of E_ib under the action of different types of defects, and propose that the presence of holes (boron dopant) and the unsaturated electrons in CNTs can generate the chemical interaction between CNT and Mg matrix effectively. Our results are of great scientific importance to the realization of robust interfacial bonding between CNTs and Mg matrix via the reinforcement modification, so as to enhance the mechanical properties of CNTs reinforced Mg matrix composites.     

Hydrogen adsorption on Pt-decorated closed-end armchair (3,3), (4,4) and (5,5) single-walled carbon nanotubes

ABSTRACT

Structures of small lengths of capped (3,3), (4,4) and (5,5) single-walled carbon nanotubes (SWCNTs) and their structures decorated by Pt atom and Pt_n clusters (n = 2–4) were obtained using density functional theory calculations. Binding abilities of Pt atom and Pt_n clusters on the outer surface of SWCNTs at various adsorption sites were explored. Adsorptions of H₂ onto Pt atom of the Pt-decorated (3,3), (4,4) and (5,5) SWCNTs were studied and their adsorption energies are reported. The thermodynamic properties and equilibrium constants for H₂ adsorptions on the Pt₄-decorated (3,3), (4,4) and (5,5) SWCNTs were obtained. The adsorption of H₂ on the Pt atom of the Pt₄/(3,3) SWCNT was found to be the most preferred reaction of which enthalpy and free energy changes at room temperature are ?46.61 and ?23.99 kcal/mol, respectively.     

BaxOy小团簇修饰Ru(0001)表面的结构稳定性和氮分子吸附性质

为了说明钡助剂的存在形式, 本文采用第一性原理方法研究了Ba_xO_y小团簇修饰Ru(0001)表面的结构稳定性和氮分子吸附性质. 基于总能的热力学分析发现, 在实验条件下(500 K, P_H2O/P_H2<10^-3), Ba₂O团簇比BaO₂, BaO, Ba和O等团簇(原子)更加稳定. 这证实含有金属性钡原子的团簇也是氧化钡助剂可能的工作状态. 表面电荷差分密度说明Ba₂O团簇的氧和钡原子与衬底的作用不同. 不过Ba₂O团簇氧和钡原子附近的氮分子吸附行为相似, Ba₂O团簇增强了氮分子和衬底的相互作用. Ba₂O团簇氧和钡原子附近的氮分子吸附能分别为0.78 和0.88 eV, 均大于清洁表面的0.67 eV. 氮分子间距和氮分子的拉伸振动频率都表明Ba₂O团簇在一定程度上活化了吸附氮分子. Ba₂O团簇氧和钡原子附近的N–N键长分别为0.117和0.116 nm, 大于清洁表面的0.114 nm. 氧和钡原子附近氮分子的拉伸振动频率分别为 1888 和1985 cm^-1, 小于清洁表面的2193 cm^-1. 电荷差分密度的计算结果说明, 削弱作用主要来自于Ba₂O团簇中钡离子和氮分子间的静电作用. 两者间的静电作用增加了氮分子π 反键轨道的占据数, 促进了氮分子极化, 从而削弱氮分子键.     

Temperature-induced transformations in hydrogenated and fluorinated single-wall carbon nanotubes studied by Raman scattering

Raman spectra of hydrogenated and fluorinated single-wall carbon nanotubes (SWCNTs) are measured at ambient temperature before and after heat treatment. The spectra of the as-prepared hydrogenated SWCNTs show a giant structureless band in the visible region that screens the Raman peaks related to the carbon atom vibrations. The onset of this strong band follows the excitation laser line, which is typical of hot luminescence. The intensity of the luminescence background decreases exponentially with the annealing time, while the dependence of the luminescence decay time constant on the annealing temperature is of the Arrhenius type with the activation energy E _a = 465 ± 44 meV. The luminescence background in the Raman spectra of the fluorinated SWCNTs is comparable with the Raman peak intensity and decreases exponentially with the annealing time. The dependence of the decay time constant on the temperature is again of the Arrhenius type with the activation energy E _a = 90 ± 8 meV. The appearance of hot luminescence is related to the upshift of the fundamental energy gap in functionalized SWCNTs and the structural disorder induced by random binding of hydrogen or fluorine atoms. The luminescence background disappears upon annealing in vacuum or in air after removal of hydrogen (fluorine), while the annealed samples still demonstrate large structural disorder.     

Cathodoluminescence study of isoelectronic doping of gallium oxide nanowires

Isoelectronic (In, Al) doped gallium oxide nanowires have been grown by a vapour solidification process. XRD and TEM were used for their structural characterization. The morphology and optical properties of the In(Al)-doped Ga₂O₃ nanowires have been investigated by means of the secondary electrons and cathodoluminescence (CL) techniques in the SEM. Red and blue-UV emission bands appear as complex bands and their components are influenced by the presence of In or Al, leading to a blue-shift of the blue-UV band usually observed in undoped gallium oxide. These In and Al related changes in the luminescence features of doped Ga₂O₃ nanostructures are discussed.     

Adsorption of hydrogen in defective carbon nanotube: modelling and consequent investigations using statistical physics formalism

ABSTRACT

Experimental adsorption isotherms of hydrogen in CNT samples (CNT-A, activated CNT-A CNT-B and activated CNT-B) at T?=?77, 87 and 90?K have been fitted using some theoretical model expressions treated by statistical physics through the grand canonical ensemble. The monolayer model with single energy is selected to fit and interpret the experimental data obtained with CNTs. The physico-chemical parameters, interfering in the adsorption process and implicated in the model expressions, could be directly determined from the experimental data through numerical simulation. Three parameters of the model are fitted, namely the number of hydrogen molecule per site n, the interstitial site density N_m and the energetic parameter P_1/2. The evolution of these parameters as function of temperature is plotted and interpreted in relation to adsorption process. Finally, the thermo-dynamic potential functions, which involve in the adsorption mechanism like free enthalpy of Gibbs G_a, internal energy E_int and entropy S_a, are derived by statistical physics calculations from the selected model.     

Isoniazid drug adsorption on the pristine and Al-doped zinc oxide nanosheets: a molecular modeling

Experimental works have exposed that Al-doping in the structure of ZnO nanostructures intensely increases their electronic sensitivity toward various chemicals. Herein, density functional theory calculations were employed to inspect the Al-doping effect on the sensitivity of a ZnO nanosheet (ZnOS) to the isoniazid (IS) drug. The pristine ZnOS physically adsorbs an IS molecule with adsorption energy (E _ad) of ?6.8?kcal/mol, and the sensing response value of 2.3 at 298?K. Replacing a Zn atom by an Al atom strengthens the interaction, increasing the E _ad to ?20.8?kcal/mol. Also, the Al-doping significantly increases the sensing response value to 150.3 by rising the electrical conductivity of the sheet. A short recovery time of 11.3 s is predicted for the Al-ZnOS-based sensor. The water solvent somewhat strengthens the interaction of IS drug with the Al-ZnOS, increasing the sensing response from 150.3 to 175.8. We concluded that the Al-doping makes the ZnOS a promising sensor for IS drug detection.     

Study on the electronic structure and hydrogen adsorption by transition metal decorated single wall carbon nanotubes

The ground state geometry and electronic structure of various 4d transition metal (TM) atom (Y, Zr, Nb and Mo) decorated single wall carbon nanotubes (SWCNTs) are obtained using density functional theory and the projector augmented wave (PAW) method. We found a systematic change in the adsorption site of the transition metal atom with increasing number of d electrons. We also predicted that Y and Zr decorated SWCNTs are metallic whereas Nb and Mo decorated SWCNTs are semiconducting. From detailed electronic structure and Bader charge analysis we found that the systematic variation of the adsorption site with the number of d electrons is related to the decreasing amount of charge transfer from the TM atom to the SWCNT along the 4d series. We have also studied the hydrogen adsorption capabilities of these decorated SWCNTs to understand the role of transition metal d electrons in binding the hydrogen molecules to the system. We found that metallic SWCNT + TM systems are better hydrogen adsorbers. We showed that the hydrogen adsorption by a TM decorated SWCNT will be maximum when all the adsorptions are physisorption and that the retention of magnetism by the system is crucial for physisorption.     

Nb-Ti-Al合金高温氧化机理电子理论研究

采用递归法计算了Nb合金的电子态密度、原子镶嵌能、亲和能和团簇能等电子结构参数,研究Nb合金高温氧化机理.研究表明,氧在Nb合金表面的吸附能较低,易在合金表面吸附,并逐渐扩散到Nb合金的基体中.氧在合金基体中镶嵌能为负值,氧的态密度和Nb相似,在Nb中具有很高的溶解度.Ti,Al在合金晶内的镶嵌能均高于各自在合金表面的镶嵌能,Ti,Al从合金内部向合金表面扩散,最终在Nb合金表面偏聚,形成富Ti,Al的表层.团簇能计算结果表明Nb合金表面的Ti,Al原子各自均有聚集倾向,分别形成Ti和Al原子团.氧与合金