纳米通道内超疏水性表面气泡的运动

疏水表面纳米气泡的运动有重要的应用价值和研究意义。本文采用分子动力学方法,模拟了纳米通道壁面为超疏水性时壁面上气泡的运动状况。在质量力驱动下,随着外界驱动力的增大,两壁面上的气泡被逐渐拉长,同时逐渐变得扁平;前端"接触角"逐渐增大,而后端"接触角"逐渐减小。纳米通道内疏水性表面的纳米气泡随着外部驱动力的变化呈现出不同的形态,变化程度随着驱动力的增大而增大。在不同驱动力作用下,两个气泡总是保持相同的速度,气泡的速度与外力驱动的大小呈线性增长趋势。随着外力的增大,边界层及通道中心速度皆呈现增大趋势。     

基于AMOEBA可极化力场研究蛋白二聚化对于gramicidin A通道电导的影响

在离子通道性质的研究中,由于可极化力场计算量巨大,长期以来使用最广泛的依旧是经典力场. 本文考察了可极化力场在描述离子通道gramicidin A(gA)二聚状态下离子输运性质方面的可靠性. 利用AMOEBA可极化力场对单通道gA和双通道gA进行增强采样模拟,从电导、扩散系数和自由能等方面描述了gA二聚化对钾离子和钠离子穿越通道过程的影响. 计算结果显示,可极化力场模拟获得的钾离子和钠离子穿越通道的电导与实验数值吻合. 进一步的数据分析揭示了蛋白质二聚化影响gA通道离子输运性质的分子机制,即蛋白二聚化通过调整gA蛋白周围的环境(磷脂头基、通道外离子和体相水分子的分布)而不是直接调整gA蛋白的构象来加速钾离子和钠离子穿越通道.     

On the turbulent thermal conductivity of a gas in the field of an external force

The kinetic relation defining turbulent thermal conductivity in the field of an external force is derived using the entropy evolution equation applied to an ideal one-component turbulent gas under the assumption of fluctuation polytropism.     

微通道中流体流动的分子动力学模拟

本文建立了周期外力作用下流体在微通道间流动模型.以此模型为基础,模拟计算了氩在亲水性和憎水性平行平板壁面间的流动过程,并对速度分布、温度分布等进行了统计.模拟结果表明在憎水性壁面附近,易观察到速度滑移和温度阶跃现象,而亲水性壁面上则反之.与N-S方程和能量方程的解进行了比较,亲水性通道速度和温度的模拟结果与分析解吻合较好,憎水性通道的模拟结果与分析解相差较大.同时,对300℃下不同密度水的流动进行了模拟,随着密度的增大,在壁面附近流体流动特性发生了变化.     

Fluctuation on Brownian motor in the presence of entropic barrier

Transporting velocity of a loaded Brownian motor with entropic barrier is investigated in the presence of an asymmetric unbiased force. It is found that in the presence of the entropic barrier, the stall force of the Brownian motor does not change monotonously with temperature. The average velocity of the Brownian motor is a peaked function of thermal noise and amplitude of the asymmetric unbiased external force, which indicates that a definite fluctuation can facilitate the loaded Brownian motor moving. With the increase of the load, the range of temperature and amplitude of the asymmetric unbiased external force for Brownian motor working become smaller. The limited area for Brownian motor working is given on the load-temperature plane. The threshold of fluctuation for Brownian motor working is found, and the minimum of asymmetric parameter of unbiased external force for Brownian motor working is given.     

粗糙纳通道内流体流动与传热的分子动力学模拟研究

为研究粗糙表面对纳尺度流体流动和传热及其流固界面速度滑移与温度阶跃的影响,本文建立了粗糙纳通道内流体流动和传热耦合过程的分子动力学模型,模拟研究了粗糙通道内流体的微观结构、速度和温度分布、速度滑移和温度阶跃并与光滑通道进行了比较,并分析了固液相互作用强度和壁面刚度对界面处速度滑移和温度阶跃的影响规律. 研究结果表明,在外力作用下,纳通道主流区域的速度分布呈抛物线分布,由于流体流动导致的黏性耗散使得纳通道内的温度分布呈四次方分布. 并且,在固体壁面处存在速度滑移与温度阶跃. 表面粗糙度的存在使得流体剪切流动产生了额外的黏性耗散,使得粗糙纳通道内的流体速度水平小于光滑通道,温度水平高于光滑通道,并且粗糙表面的速度滑移与温度阶跃均小于光滑通道. 另外,固液相互作用强度的增大和壁面刚度的减小均可导致界面处速度滑移和温度阶跃程度降低. 关键词： 速度滑移 温度阶跃 流固界面 粗糙度     

Generation of Multi-ion Graph States with Trapped Ions in Thermal Motion

We propose a scheme for generating multi-ion graph states using many trapped ions in thermal motion. Our generation scheme is insensitive to external state since the interaction between ions and laser fields does not involve the external degree of freedom. The scheme can be well realized within the current experimental technique.     

Pressure Tuning of Magnetism and Drastic Increment of Thermal Conductivity under Applied Magnetic Field in HgCr_2S_4

HgCr_2S_4 is a typical compound manifesting competing ferromagnetic(FM) and antiferromagnetic(AFM) exchanges as well as strong spin-lattice coupling.Here we study these effects by intentionally choosing a combination of magnetization under external hydrostatic pressure and thermal conductivity at various magnetic fields.Upon applying pressure up to 10 kbar at 1kOe,while the magnitude of magnetization reduces progressively,the AFM ordering temperature T_N enhances concomitantly at a rate of about 1.5K/kbar.Strikingly,at 10 kOe the field polarized FM state is found to be driven readily back to an AFM one even at only 5 kbar.In addition,the thermal conductivity exhibits drastic increments at various fields in the temperature range with strong spin fluctuations,reaching about 30% at 50 kOe.Consequently,the results give new experimental evidence of spin-lattice coupling.Apart from the colossal magnetocapacitance and colossal magnetoresistance reported previously,the findings here may enable new promising functionalities for potential applications.     

Atomic force microscopy-based repeated machining theory for nanochannels on silicon oxide surfaces

The atomic force microscopy (AFM)-based repeated nanomachining of nanochannels on silicon oxide surfaces is investigated both theoretically and experimentally. The relationships of the initial nanochannel depth vs. final nanochannel depth at a normal force are systematically studied. Using the derived theory and simulation results, the final nanochannel depth can be predicted easily. Meanwhile, if a nanochannel with an expected depth needs to be machined, a right normal force can be selected simply and easily in order to decrease the wear of the AFM tip. The theoretical analysis and simulation results can be effectively used for AFM-based fabrication of nanochannels.     

Exact density matrix of an oscillator-bath system: Alternative derivation

Starting from a total Lagrangian describing an oscillator-bath system, an alternative derivation of exact quantum propagator is presented. Having the quantum propagator, the exact density matrix, reduced density matrix of the main oscillator and thermal equilibrium fixed point are obtained. The modified quantum propagator is obtained in the generalised case where the main oscillator is under the influence of a classical external force. By introducing auxiliary classical external fields, the generalised quantum propagator or generating functional of position correlation functions is obtained.     

Thermal fluctuation electromagnetic field as a reason for the sensitivity of a condensed diamagnetic medium to weak actions

Interaction between the thermal fluctuation electromagnetic field of a condensed medium and a weak external factor, say, a weak effective magnetic field including an external magnetic field, rigid rotation of the medium, and Coriolis force, imparts a torque to any charged free or bound particles (atoms, molecules, etc.). which indicates that the medium is sensitive to weak actions. The torque is proportional to thermal energy kT and may increase substantially under the cyclotron resonance conditions. The so-called kT problem is solved, so that many observations having to do with the field of physics that can be called the physics of weak actions (?kT) can now be theoretically explained.     

有结构壁面上液滴运动特征的耗散粒子动力学模拟

本文采用耗散粒子动力学方法, 研究了恒定外力驱动下液滴在有结构壁面上的运动过程. 通过研究液滴在通过壁面结构时前缘接触点和前进角的变化, 分析了液滴的运动特征. 研究结果表明, 在不同润湿性或不同外力驱动下, 存在使液滴运动最快的“最优”壁面结构, 并对其机理进行了讨论. 本文还探讨了壁面润湿性、热涨落以及外力对液滴运动状态的影响. 关键词： 微流体 有结构壁面 润湿性 耗散粒子动力学(DPD)     

Monte Carlo analysis of polymer translocation with deterministic and noisy electric fields

Polymer translocation through the nanochannel is studied by means of a Monte Carlo approach, in the presence of a static or oscillating external electric voltage. The polymer is described as a chain molecule according to the two-dimensional “bond fluctuation model”. It moves through a piecewise linear channel, which mimics a nanopore in a biological membrane. The monomers of the chain interact with the walls of the channel, modelled as a reflecting barrier. We analyze the polymer dynamics, concentrating on the translocation time through the channel, when an external electric field is applied. By introducing a source of coloured noise, we analyze the effect of correlated random fluctuations on the polymer translocation dynamics.     

Directed transport of coupled Brownian ratchets with time-delayed feedback

A time-delayed feedback ratchet consisting of two Brownian particles interacting through the elastic spring is consid ered. The model describes the directed transport of coupled Brownian particles in an asymmetric two-well ratchet potential which can be calculated theoretically and implemented experimentally. We explore how the centre-of-mass velocity is af fected by the time delay, natural length of the spring, amplitude strength, angular frequency, external force, and the structure of the potential. It is found that the enhancement of the current can be obtained by varying the coupling strength of the delayed feedback system. When the thermal fluctuation and the harmonic potential match appropriately, directed current evolves periodically with the natural length of the spring and can achieve a higher transport coherence. Moreover, the external force and the amplitude strength can enhance the directed transport of coupled Brownian particles under certain conditions. It is expected that the polymer of large biological molecules may demonstrate a variety of novel cooperative effects in real propelling devices.     

Influence of electric and magnetic fields on the shock wave configuration at the diffuser inlet

The possibility is investigated of influencing the shock wave configuration in a xenon plasma flow at the inlet of a supersonic diffuser by applying electric and magnetic fields. Flow patterns resulting from interaction of the plasma with external fields in the entire diffusor volume and its different sections are compared. The patterns are obtained by the Schlieren method using two recording regimes: individual frames or a succession of frames. The study focuses on the normal shock wave formation process under strong MHD interaction over the whole diffuser volume. Basic factors affecting the plasma flow velocity in the diffuser under externally applied fields are compared, namely, the ponderomotive force and the Joule heating of the gas by the electric field, which decelerate the supersonic flow, and the heat removal to the external electric circuit producing the opposite effect. It has been shown that the external fields are most effective if applied to the inlet part of the diffuser, while the flow in the diffuser section, where there is a large density of dissipative structures, is not readily responsive to external factors. It is suggested that the measure of response can be estimated by the energy that goes to the shock wave formation as a result of the flow interaction with the diffuser walls.     

Elementary pinning forces measured using low temperature scanning electron microscopy

Magnetic flux penetrating Josephson tunnel junctions parallel and transverse to the tunnel barrier has been imaged using low temperature scanning electron microscopy. Employing this technique we have studied the behavior of magnetic flux quanta under the influence of external forces. The strength of pinning centers acting on vortices existing within the barrier has been determined by measuring the turning angle of these flux quanta in rotating magnetic fields. Trapped transverse flux quanta could be depinned by applying a sufficient Lorentz force or electron beam irradiation. The strength of the pinning centers has been determined.     

A stochastic approach to open quantum systems

Stochastic methods are ubiquitous to a variety of fields, ranging from physics to economics and mathematics. In many cases, in the investigation of natural processes, stochasticity arises every time one considers the dynamics of a system in contact with a somewhat bigger system, an environment with which it is considered in thermal equilibrium. Any small fluctuation of the environment has some random effect on the system. In physics, stochastic methods have been applied to the investigation of phase transitions, thermal and electrical noise, thermal relaxation, quantum information, Brownian motion and so on. In this review, we will focus on the so-called stochastic Schr?dinger equation. This is useful as a starting point to investigate the dynamics of open quantum systems capable of exchanging energy and momentum with an external environment. We discuss in some detail the general derivation of a stochastic Schr?dinger equation and some of its recent applications to spin thermal transport, thermal relaxation, and Bose-Einstein condensation. We thoroughly discuss the advantages of this formalism with respect to the more common approach in terms of the reduced density matrix. The applications discussed here constitute only a few examples of a much wider range of applicability.     

The instability of electrostatic wave in a magnetized dusty plasma with nonadiabatic dust charge fluctuation

The effects of external magnetized field and nonadiabatic dust charge fluctuation on instability of wave incorporating the nonthermally distributed ions and the temperatures of ion and dust in dusty plasmas are investigated. A linear dispersion relation is obtained. The numerical results show that the external magnetized field, fast ions and nonadiabatic dust charge fluctuation have strong influence on the frequency and the damping of wave.     

导电石墨烯孔道内双电层结构的研究

为有效开发和利用新能源,人们迫切需要高性能的超级电容器提供能量的存储和转换.在超级电容器中双电层结构扮演着关键性的角色.本文利用分子动力学方法通过建立开放的石墨烯纳米孔道(1～2 nm),研究了KCl溶液在纳米孔道内的双电层结构,同时也比较了恒电量模拟(Q)和恒电势模拟法(U)下双电层结构的异同.结果表明在恒电势模拟法考虑了导电石墨烯壁的镜像作用使结果更符合实验中的材料系统.而石墨烯壁的镜像作用能额外吸附离子从而增强孔道内部的阴阳离子,这可能有助于电极电容的提升.通过对不同孔道高度的研究,本文发现水分子作为介电材料在水基超级电容器中发挥着决定性的作用.它能在很大程度上抵消不同离子和不同孔道高度下双电层的变化,从而在不同情况下获得了相似的电容.     

基于麦克斯韦电磁场理论的神经元动力学响应与隐藏放电控制

钙、钾、钠等离子在细胞内连续泵送和传输时产生的时变电场不仅会影响神经元的放电活动,而且会诱导时变磁场去进一步调节细胞内离子的传播.根据麦克斯韦电磁场理论,时变的电场和磁场在细胞内外的电生理环境中会相互激发而产生电磁场.为了探究电磁场影响下的神经元放电节律转迁,本文在三维Hindmarsh-Rose(HR)神经元模型的基...