碳纳米管熔接金电极的分子动力学模拟

利用分子动力学模拟方法,研究了单壁碳纳米管与Au电极的高温熔接. 模拟结果表明,用端口吸附了Au团簇的碳纳米管在高温下能很好地与Au电极熔接. 首先将Au团簇放置于碳纳米管开口处进行高温退火,退火温度在1100 K左右,Au团簇部分Au原子进入碳纳米管管内,吸入碳纳米管中的Au原子形成壳层螺旋结构的Au纳米线,管外Au团簇呈无定形结构. 然后将吸附了Au团簇的碳纳米管与Au电极进行熔接,高温退火后,碳纳米管与Au电极表面之间形成了稳固的熔接,熔接最佳温度在800 K左右. 关键词： 碳纳米管 金电极 分子动力学模拟     

碳纳米管内Ni纳米线的螺旋度与热稳定性研究

本文采用分子动力学模拟方法研究了扶手型碳纳米管包裹Ni纳米线的复合结构, 主要讨论内部Ni纳米线的螺旋度和热稳定性.结果表明, Ni纳米线为多壳层螺旋结构, 各壳层是由多条Ni原子链螺旋而成,不同层的螺旋度不同,内层的螺旋度明显大于外层. 当每层的Ni原子链条数为3的整数倍时,其螺旋度最大. Ni纳米线的螺旋度与碳纳米管的管径相关,各层螺旋度的大小随管径的增加有明显的周期性变化. 碳纳米管对Ni纳米线有很好的保护作用,即使是高温对Ni纳米线的结构及螺旋度也影响很小.     

碳纳米管包裹的硅纳米线复合结构的热稳定性研究

采用经典分子动力学方法模拟一定直径[111]晶向的硅纳米线填充不同扶手椅型单壁碳纳米管复合结构的加热过程, 通过可视化和能量分析的方法判断复合结构中硅纳米线和碳纳米管的热稳定性. 通过讨论碳纳米管的空间限制作用和分子间相互作用力的关系, 对碳纳米管和硅纳米线的热稳定性变化进行初步解释. 研究发现碳纳米管中硅纳米线的热稳定性和碳纳米管的直径关系密切: 当管径较小时, 硅纳米线的热稳定性有所提高, 当管径增大到一定大小时, 硅纳米线的热稳定性会突然显著地下降, 直到硅纳米线与管壁不存在分子间相互作用力, 硅纳米线的热稳定性才会恢复. 而硅纳米线填充到碳纳米管中对碳纳米管的热稳定性有着明显的降低作用.     

碳纳米管-硅纳米线复合结构的形成和热稳定性

通过分子动力学方法模拟了在碳纳米管内填充一定数目的半导体元素硅形成碳纳米管-硅纳米线复合结构的过程,并采用Lindemann指数研究了这种复合结构的热稳定性．计算结果表明,当考虑碳纳米管和硅纳米线轴向方向的周期性边界条件之后,在C（13,0）和C （14,0）碳纳米管内能够形成亚稳结构的硅纳米线Si₁₆NW和Si₂₀NW,从而获得一种碳纳米管-硅纳米线的新型复合结构．通过计算这种复合结构的Lindemann指数,可以看到由于碳纳米管的保护作用,碳纳米管包裹的硅纳 关键词： 复合结构 纳米线 碳纳米管 分子动力学     

金属Ni纳米线凝固行为的分子动力学模拟

采用EAM镶嵌原子作用势，通过经典的分子动力学模拟方法研究了不同冷却速度下的金属Ni纳米线的凝固行为，并给出了纳米线在凝固区域的结构演变过程.利用键对分析技术研究了在不同冷却速度下体系中的原子团簇在降温过程中的变化情况.研究表明，纳米线的凝固起始于表面原子，并且随着冷却速度的降低，Ni纳米线的微观结构从非晶态过渡到多壳螺旋结构，最终达到稳定的面心立方结构.多壳螺旋结构同时具有确定的结晶温度和长程无序、短程有序的非晶结构的特征. 关键词： 纳米线 凝固行为 分子动力学 键对分析     

超细Pt纳米线结构和熔化行为的分子动力学模拟研究

基于EAM原子嵌入势, 对临界尺寸下的自由Pt纳米线的奇异结构和熔化行为进行分子动力学模拟. 模拟结果显示, 超细Pt纳米线的熔点随径向尺寸和结构的不同而发生明显改变; 引入林德曼因子, 令其临界值为0.03, 以此得到对应熔点值大小与通过势能-温度变化曲线找出的一致, 又比较了纳米线各层粒子平均林德曼指数的大小, 对各层纳米结构的热稳定性进行定量标度; 综合分析发现螺旋结构纳米线的熔化从内核开始, 而多边形结构的纳米线的熔化从外壳层开始.     

尺寸效应对Al纳米线凝固行为的影响

结合EAM镶嵌原子作用势, 通过经典的分子动力学模拟研究了不同截面尺寸Al纳米线在两种冷却速率下的凝固行为, 并采用键对分析技术探讨了相变过程中原子团簇的演化情况. 结果表明:Al纳米线的最终结构不仅与冷却速率有关, 还呈现出明显的尺寸效应. 在较快的冷却速率下, 五种截面尺寸的Al纳米线均得到了多壳螺旋结构; 而当冷却速率降低以后, 除了N₃纳米线发生了断裂以外, 其余纳米线的结构随着截面尺寸的增加, 逐渐从多壳螺旋结构经由类-六边形多壳结构最终过渡到稳定的晶态结构.     

Au纳米薄膜的熔化机理及其结构演变的分子动力学模拟

利用分子动力学模拟详细研究了不同厚度的Au纳米薄膜的熔化机理和结构演变. 模拟结果表明所有Au纳米薄膜的熔化行为分为两个阶段,即表面预熔和均相熔化. 只有最外层原子出现了预熔化行为, 其他内层原子在均相熔化之前始终保持稳定的固态,这与零维的Au纳米团簇和一维的Au纳米线的预熔化行为是不同的. 同时Au纳米薄膜的熔化温度随着薄膜厚度的增加而升高. 在预熔化过程中,在原子水平上发现了所有的Au纳米薄膜的f100g晶面向f111g晶面转变的表面重建过程. 对于最薄的L2纳米薄膜,当温度低于500 K 时表面应力不能诱导这样的表面重建. 然而一维的Au纳米线在更低温度下就能够观察到了由表面应力诱导的表面重建过程. 这主要是因为Au纳米线具有更高的比表面积所导致的. 另外研究结果还表明当模拟温度达到某一特定值时,由双原子层组成的Au纳米薄膜能够分裂成一维的纳米线.     

尺寸效应对Al纳米线凝固行为的影响

结合EAM镶嵌原子作用势, 通过经典的分子动力学模拟研究了不同截面尺寸Al纳米线在两种冷却速率下的凝固行为, 并采用键对分析技术探讨了相变过程中原子团簇的演化情况. 结果表明:Al纳米线的最终结构不仅与冷却速率有关, 还呈现出明显的尺寸效应. 在较快的冷却速率下, 五种截面尺寸的Al纳米线均得到了多壳螺旋结构; 而当冷却速率降低以后, 除了N₃纳米线发生了断裂以外, 其余纳米线的结构随着截面尺寸的增加, 逐渐从多壳螺旋结构经由类-六边形多壳结构最终过渡到稳定的晶态结构.     

模拟研究碳纳米管的热稳定性质

运用分子动力学方法具体模拟研究单个碳纳米管（CNTs）在加热过程中的结构变化．选择多组不同结构的单壁碳纳米管（SWCNTs）和双壁碳纳米管（DWCNTs）作为研究对象,加热温度从室温开始到4000 K,压强保持为1 atm．结果表明单壁碳管中手性型结构热稳定性最好,其次是扶手椅型和锯齿型,当手性角相同时,直径大的热稳定性更高;对于双壁碳管,研究表明当双壁中至少之一为手性结构时其热稳定好,而内外壁均为锯齿结构的稳定性最差,该结果进一步支持了有关单壁碳管的结论;还从理论上探索了描述结构热稳定性的方式,并在键层 关键词： 单壁碳纳米管 双壁碳纳米管 分子动力学方法 热稳定性能     

First-principles study on structural and electronic properties of copper nanowire encapsulated into GaN nanotube

We present a systemic study of the structural and electronic properties of Cu_n nanowires (n=5, 9 and 13) encapsulated in armchair (8,8) gallium nitride nanotubes (GaNNTs) using the first-principles calculations. We find that the formation processes of these systems are all exothermic. The initial shapes are preserved without any visible changes for the Cu₅@(8,8) and Cu₉@(8,8) combined systems, but a quadratic-like cross-section shape is formed for the outer nanotube of the Cu₁₃@(8,8) combined system due to the stronger attraction between nanowire and nanotube. The electrons of Ga and N atoms in outer GaN sheath affect the electron conductance of the encapsulated metallic nanowire in the Cu₁₃@(8,8) combined system. But in the Cu₅@(8,8) and Cu₉@(8,8) combined systems, the conduction electrons are distributed only on the copper atoms, so charge transport will occur only in the inner copper nanowire, which is effectively insulated by the outer GaN nanotube. Considering the maximal metal filling ratio in nanotube, we know that the Cu₉@(8,8) combined system is top-priority in the ultra-large-scale integration (ULSI) circuits and micro-electromechanical systems (MEMS) devices that demand steady transport of electrons.     

Helical gold nanotube synthesized at 150 K

Gold nanowires were synthesized at 150 K by electron beam thinning of a gold thin foil in an UHV electron microscope. The gold nanowires were found to have a helical multishell structure (HMS). One particular nanowire, which was thinner than the 7-1 HMS nanowire, was found to have a tubular structure. The gold single wall nanotube is composed of five atomic rows that coil about the tube axis. The diameter was 0.4 nm and the pitch was 11 nm. The stability of the (5,3) nanotube was discussed in terms of the shear deformation of the triangular network of gold atoms.     

Ab initio study of iron nanowires encapsulated inside silicon nitride nanotubes

In the present paper, the iron nanowires (containing single Fe atomic chain and Fe_n nanowire (n=5, 9 and 13)) encapsulated in (8,8) silicon nitride nanotubes (SiNNTs) have been investigated systematically using the first-principles within GGA. For the pristine (8,8) SiNNT, a ferromagnetic ground state is more favorable, and the semiconducting character is observed. After single Fe atom chain encapsulated inside (8,8) SiNNT, two possible configurations are determined depending on the distance from the wire to the tubewall. Furthermore, these two configurations keep high spin-dependent transport and thus can be used in spintronics devices. As for the Fe_n nanowires encapsulated in (8,8) SiNNTs (Fe_n@(8,8)), the spin-dependent transport are badly disturbed, but the stabilities of metal wires are reinforced in Fe_n@(8,8) systems. In particular, an enhanced ferromagnetism is observed after the Fe₁₃ nanowire encapsulated into the (8,8) SiNNT. The results suggest that the Fe_n@(8,8) systems can be used in the magnetic storage industries.     

稀有气体原子注入缺陷性纳米碳管的分子动力学模拟

采用TLHT势和经典分子动力学方法研究了稀有气体原子(He，Ne，Ar，Kr，Xe)进入带缺陷的单壁纳米碳管(SWCNT)的动力学过程，计算出了稀有气体原子分别从管壁和管口入射时，它们能封装在SWCNT中的能量阈值E_k0，并与理想结构情形做了比较.结果表明：随着管壁缺陷半径r的增加，E_k0减小；当r<4.5 ?时，给定合适的初始动能，稀有气体原子能封装在纳米碳管中；而r=4.5 ?时，稀有气体原子不能封装在碳管中，且此时缺陷对Ar，Kr和Xe的输运特性有很大影响. 关键词： 纳米碳管 缺陷 稀有气体原子 分子动力学模拟     

Tubular fullerenes inside carbon nanotubes: optimal molecular orientation versus tube radius

We present an investigation of the orientations and positions of tubular fullerene molecules (C₉₀, ..., C₂₀₀) encapsulated in single-walled carbon nanotubes (SWCNT), a series of so-called fullerene nanopeapods. We find that increasing the tube radius leads to the following succession of energetically stable regimes: (1) lying molecules positioned on the tube's long axis; (2) tilted molecules on the tube's long axis; and (3) lying molecules shifted away from the tube's long axis. As opposed to C₇₀ and C₈₀ molecules encapsulated in a SWCNT, standing orientations do not develop. Our results are relevant for the possible application of molecular-orientation-dependent electronic properties of fullerene nanopeapods, and also for the interpretation of future experiments on double-walled carbon nanotube formation by annealing fullerene peapod systems.     

Mechanical properties of nickel-coated single-walled carbon nanotubes and their embedded gold matrix composites

The effects of nickel coating on the mechanical behaviors of armchair single-walled carbon nanotubes (SWCNTs) and their embedded gold matrix composites under axial tension are investigated using molecular dynamics (MD) simulation method. The results show that the Young's moduli and tensile strength of SWCNTs obviously decrease after nickel coating. For armchair SWCNTs, the decreased ratio of the Young's moduli of SWCNTs with smaller radius is larger than that of SWCNTs with larger radius. A comparison is made between the response to Young's modulus of a composite with parallel embedded nanotube and the response of a composite with vertically embedded nanotube. The results show that the uncoated SWCNT can enhance the Young's modulus of composite under the condition of parallel embedment, but such improvement disappears under the condition of vertical embedment because the interaction between SWCNT and gold matrix is too weak for effective load transfer. However, the nickel-coated SWCNT can indeed significantly improve the composite behavior.     

Comparison of the structural,electronic and magnetic properties of Fe,Co and Ni nanowires encapsulated into silicon carbide nanotube

A similar optimized structure, i.e. a near square cross-section shape for outside nanotube and a relative rotation between nanowire and its outside nanotube, is obtained for the transition-metal M₁₃ (M = Fe, Co, Ni) nanowires with the FCC structure encapsulated inside the armchair (8, 8) silicon carbide nanotube [ M₁₃@(8, 8)] . It is also found that the stabilities of M₁₃ nanowires are enhanced by silicon carbide nanotube encapsulation. Although the spin polarization P of each hybrid system is slightly lowered with respect to the corresponding free-standing nanowire, the largest spin polarization value 71% of Co₁₃@(8, 8) among the three hybrid systems suggests it could be utilized to construct efficient spin transport devices. As compared with the corresponding free-standing nanowire, the magnetic moments μ₁ and μ₂ for the peripheral M₁ (especially) and M₂ atoms are decreased, while the magnetic moments μ₃ and μ₄ for the interior M₃ and M₄ atoms are increased for each M₁₃@(8, 8) hybrid system. In particular, different from the bulk FCC Fe that is antiferromagnetic, the minimum energy magnetic structure of FCC Fe₁₃ free-standing nanowire is ferromagnetic. Furthermore, contrary to the cases of Co₁₃ and Ni₁₃ nanowires, the ferromagnetism is further enhanced after Fe₁₃ nanowire is encapsulated inside (8, 8) silicon carbide nanotube.