非定常膨胀过程中水蒸汽凝结对流场影响的数值分析

采用数值目的对激波管非定常膨胀过程中,汽液相变与流场的相互作用进行了模拟.主要研究了含有水蒸汽的混合气体在激波管中的非平衡凝结过程以及其对流场的作用.结果表明由于水蒸气的凝结释放热量对流场局部进行加热,使流场参数发生扰动而产生凝结激波.经过与凝结激波的相互作用后,流场参数和结构将发生明显的变化.     

低频Alfvén波多波相干加热粒子模拟

采用粒子模拟方法,考察多支沿背景磁场方向传播的低频Alfvén波对磁化等离子体的加热过程,研究不同频率的多支低频Alfvén波相干加热.结果表明可以通过调整波的频率比实现对非共振加热过程和随机加热过程这两个阶段的强化.符合相干共振条件的多波加热会强化低频Alfvén波对粒子拾取,进而强化非共振加热,明显提高加热效率.在多波加热的过程中,如果多支波之间的频率差足够小,则多波在调制过程中会形成波包.波包的出现标志着粒子各向异性的强化,从而提升随机加热效率.     

来流边界层效应下斜坡诱导的斜爆轰波

以超声速预混气中的斜爆轰波为研究对象,对其在来流边界层效应下的特性进行了实验研究.在马赫数为3的超声速预混风洞中,通过斜坡诱导产生了斜爆轰波.当来流的当量比较低时,预混气中产生的是化学反应锋面与激波面非耦合的激波诱导燃烧现象.此时边界层分离区中的化学反应放热将使分离区尺度显著增大,流场非定常性显著增强,激波位置剧烈振荡.当来流的当量比较高时,预混气将产生斜爆轰波.此时边界层分离区会影响到斜爆轰波起爆时的形态.在小尺度分离区下,斜爆轰波起爆时呈突跃结构(有横波);在中等尺度分离区下,流场固有的非定常性使斜爆轰波呈间歇突跃结构;在大尺度分离区下,斜爆轰波起爆则呈完全的平滑结构(无横波).     

基于大涡模拟下风力机翼型非定常转捩流动的动态模态分解分析

翼型绕翼流动对风力机整机性能产生重要影响.本文基于大涡模拟方法,得到风力机翼型非定常转捩流动.通过对压力流场的动态模态分解(DMD)分析,发现翼型层流分离泡的生成和发展为流动主要非定常特征,且该特征具有主要频率.预估得到高增长率T-S扰动波频率与DMD模态频率接近,发现高频变化的分离泡由边界层分离点下游不远处的T-S扰动波诱导K-H不稳定性而主导,以及中低频的DMD模态表现为T-S扰动波所引起的湍流结构.对比不同攻角下的DMD分解结果,发现上表面分离泡会逐渐向前移动,长度变短;而下表面分离泡略微后移,长度变化不大.     

平板边界层转捩过程中低频信号的产生

利用Fourier频谱分析和小波变换处理在平板边界层转捩过程中测得的速度信号,观察到频谱中存在低于基本扰动波频率的含能信号,即文中所谓的低频信号.在进一步分析中,发现这种低频信号的产生可能与流动的间歇性有关.由于流动的间歇性导致速度信号的脉动,数据结构产生间歇变化,这种信号并不一定对应于流场中的某一物理结构的真实频率 关键词： 边界层 转捩 Fourier频谱分析 小波变换     

专题：拓扑物理前沿与应用

正编者按从凝聚态物理中的电子到经典物理系统中的光波和声波,按意愿对粒子和波的传输进行调控,一直是人们孜孜不倦探索和追寻的目标,其导致了现代半导体和光电子、电声等信息产业的诞生和蓬勃发展.然而在传统材料中,由于存在着难以避免的缺陷和杂质,以及由于加工制造过程引入的粗糙度等,使得粒子与波在传输过程中产生大量的散射和损耗,从而引入了大量的噪声和提高了功耗,极大地制约了相关技术的应用与发展.因而,如何减小粒子和波在传输过程中(特别是长程传输过程     

空气流场中气泡示踪粒子的跟随性研究

在流场速度场测量中 ,示踪粒子是显示流场运动的媒介和工具 ,示综粒子对流场的跟随性直接影响着流场速度场测量的精度。本文从 Bassat- Boussinesq- Oseen( BBO) [1 ]方程出发给出了粒子跟随性函数和粒子在匀角速旋转流体中的运动公式 ,讨论了影响示踪粒子跟随性的参数     

强梯度复杂流场中的粒子动力学响应试验研究

示踪粒子在(高)超声速流场中的动力学响应是粒子成像测速等粒子示踪测量技术的关键问题之一.现有文献对粒子动力学响应的试验测量往往是通过单个斜激波响应的测量方法.然而,当示踪粒子用于测量高速飞行器发动机内部复杂的激波串流场时,粒子将经历由多道激波导致的速度、压力、黏性等剧烈变化.本文结合目前(高)超声速飞行器的研究热潮,重点关注示踪粒子在应用于发动机内部具有连续激波的复杂流场测量中存在的跟随性评估方面,开展了一系列的相关试验研究.包括测量超声速风洞的喷管出口速度分布以验证测试系统的性能,在马赫4.2和3.0流场中测量了粒子对二维10°和15°单斜劈绕流中的斜激波动力响应,并测量了模拟发动机内部连续梯度的双斜劈粒子斜激波动力响应.结合粒子动力学的理论模型,得到了各状态的粒子弛豫时间、弛豫距离、Stokes数.基于图像方法、统计学规律分析了激波非定常抖动对测量结果的影响,并对测量结果进行了修正.结果显示,相同斜劈角度下,马赫数越高,粒子的弛豫时间、弛豫距离就越大.但是在相同的来流马赫数下,斜劈角度越大,粒子的弛豫时间、弛豫距离反而减小.在强梯度之后由于流场的雷诺数和黏性系数变化剧烈,粒子的跟随性降低了大约5.7%,stokes数增加了约1%.虽然在本文条件下Stokes数仍满足超声速流场对粒子跟随性的要求,但粒子响应的降低无疑是值得关注的,尤其是当其被应用于具有更多连续梯度的复杂流场测量中.     

波转子内部非定常流动分析

为进一步了解波转子内部流动机理,本文利用数值方法分析了径流与轴流波转子内部流动,得出以下结论:模拟的流场特征与设计要求相符.计算结果充分显示了波转子内不同能量密度的气体实现能量交换的过程,同时也显示了端口非瞬时开放等非定常过程的影响.     

激光等离子体共振吸收的波碎过程

用理论分析和粒子模拟方法对激光等离子体共振吸收的波碎过程进行了研究．讨论了温度参量对共振吸收的影响，发现在共振区域电子不但会被其在静电波势阱中的振荡加热，也会被朗道阻尼所加热；在低密度区域还存在着湍动加速机制．在一定的功率水平下，可以观察到二次波碎行为     

Wave coagulation of a polydisperse gas suspension in the technology of gasification and Cryostatting of liquefied natural gas

We analyze the flow of a polydisperse suspension of methane droplets in a plane channel with simultaneous coagulation of disperse fraction particles under the action of the wave field generated in the carrier medium—gaseous methane—by oscillating parts of the channel walls. The frequency of in-phase oscillations of the walls is equal to the fundamental frequency for the transverse cross section of the channel filled with gaseous methane. In the vicinity of the radiator, a standing wave of the velocity field forms in the direction transverse to the flow and the intensity of coagulation of particles from different fractions upon their collisions increases due to mutual displacement. We describe the evolution of the dispersiveness of a vapor-droplet flow under the action of the wave field of a standing wave whose front moves transversely to the flow.     

Microsphere manipulation using ferroelectric liquid crystals

We propose a strategy for a micromanipulation method using SSFLC (surface stabilized ferroelectric liquid crystals). By adjusting the frequency of the applied ac electric field, the surface layers that cannot follow an applied ac electric field are constructed in SSFLC. In addition, by applying a sawtooth wave voltage, net flow along the smectic layer is generated. The flow direction is reversed by changing the polarity of the sawtooth wave. Consequently, the particles dispersed in SSFLC can be driven bidirectionally along the smectic layer. The particle velocity depends on the temperature, amplitude, and frequency of the applied voltage.     

Polarization of light backscattered by small particles

We study scattering of light by wavelength-scale spherical, cubic, and spheroidal particles as well as clusters of spherical particles for equal-volume-sphere size parameters 4≤x≤10 and refractive indices 1.1≤m≤2.0. Such particles exhibit three specific features in the regime of backscattering: first, the intensity shows a backscattering peak; second, the degree of linear polarization for unpolarized incident light is negative; and, third, the depolarization ratio is double-lobed. We find that the overall characteristics of the scattering-matrix elements can be explained by an internal field composed of waves propagating in opposite directions near the particle perimeter and forming standing waves, as well as a wave propagating forward with the wavelength of the internal medium. When moving from the central axis of the particle toward its perimeter, the internal field changes from a forward-propagating wave with a wavelength dictated by the particle refractive index toward a standing wave with an apparent wavelength of the surrounding medium. The mapping of the internal field to the scattered far field is like an interference dial where rotation of the dial by a quarter of a wavelength on the particle perimeter results in a change from a destructive to constructive interference feature in the angular patterns (or vice versa). The dial is a manifestation of a well-known rule of thumb: the number of maxima or minima in the scattering-matrix elements is given by the size parameter. We explain the backscattering peak as deriving from the backward-propagating internal wave near the particle perimeter. Negative polarization follows from the spatial asymmetry of the internal fields: inside the particle, the fields are amplified near the central plane perpendicular to the polarization state of incident light, resulting in more pronounced interference effects for the perpendicular polarization than for the parallel polarization. The double-lobe feature in the depolarization results from the same internal-field structure with leading cross-polarized fields located slightly different from the copolarized fields. We discuss practical implications of these findings for the retrieval of particle sizes, shapes, and refractive indices from observations and laboratory experiments.     

Driven magnetic particles on a fluid surface: pattern assisted surface flows

Magnetic microparticles suspended on the liquid-air interface and subjected to an alternating magnetic field exhibit spontaneous formation of dynamic localized snake patterns. These patterns are accompanied by four large-scale hydrodynamic vortices located at the opposite ends of the snake patterns. We report detailed studies of these large-scale vortices and their relationship to the collective response of magnetic particles in the presence of an alternating magnetic field. We present a model based on the amplitude equation for surface waves coupled to the large-scale hydrodynamic mean flow equation. The model describes both the formation of the dynamic snake patterns and the induced structure of the experimentally observed hydrodynamic flows.     

强声波作用下煤颗粒周围气体的振荡流动特性

根据二维非稳态层流的质量和动量守恒方程,研究强声波作用下煤颗粒周围气体的振荡流动特性.入射波的振幅远大于颗粒特征长度,声雷诺数小于20.根据通用微分方程的解,详细分析不同声雷诺数与斯特劳哈尔数下,颗粒壁面的流场分布、轴向压力梯度、切向应力及分离角的分布,发现在低频（~50 Hz）时,颗粒壁面轴向压力梯度、切向应力及流动分离角的分布主要受曲率效应影响,其变化规律与振荡速度的幅值变化相对应;在高频时（~5 000 Hz）,颗粒壁面轴向压力梯度、切向应力及流动分离角的分布同时受到曲率效应和流动加速度的影响.为进一步研究强声波强化煤颗粒燃烧提供理论基础.     

Comparison of photonic nanojets key parameters produced by nonspherical microparticles

Photonic nanojet (PNJ) phenomenon arising near transparent dielectric microparticles subject to plane wave illumination in the visible is considered. The near-field light scattering patterns produced by shaped wavelength-sized particles (hexahedron, cuboid, sphere, hemisphere, axicon, assembled particles) are numerically simulated and key PNJ parameters are analyzed. Particle shape influence on the peak intensity and spatial resolution of produced PNJ is investigated. We demonstrate that due to the reciprocal action of spherical-type and conical-type focusing of the special type of composite particles constituted of a hemisphere and an axicon can produce highly localized PNJ with peak intensity considerable higher than that for isolated regular particle (sphere, microaxicon, hemisphere).     

Peristaltic Motion of a Particle-Fluid Suspension in a Planar Channel

We analyze the mechanics of peristaltic pumpingof a particle-fluid suspension in a channel. Aperturbation series (to second order) in dimensionlesswave number of an infinite harmonic travelling wave is used to obtain an explicit form for thevelocities and a relation between the flow rate and thepressure gradient in terms of the Reynolds number,concentration of the particles, suspension parameters, and the occlusion. We discuss the effect of theconcentration of the particles, the Reynolds number, andthe wave number on the pressure rise, peristalticpumping, augmented pumping, and backward pumping. We also discuss the phenomenon oftrapping.     

利用体声波微流阱阵列捕获微米级颗粒

提出了一种利用体声波微流阱在三维流体空间中捕获微米级颗粒的方法,制备了2种体声波微流阱阵列,并采用有限元法进行仿真计算,求解方程得到一阶声场、二阶声场,仿真分析了聚苯乙烯微粒在流场中的运动情况。实验结果显示体声波微流阱能够快速、高效捕获三维流体空间中的微米级颗粒,实验结果与仿真结果吻合良好,圆柱型体声波微流阱与圆孔型体声波微流阱都能在几十秒内捕获三维空间中的微粒,且圆柱型体声波微流阱的捕获效率比圆孔型体声波微流阱高。该方法突破了声表面波微流阱无法操控三维空间中的微粒的局限,提高了捕获微粒的效率。      

Effect of internal waves on the sea surface in two-dimensional case

A nonlinear model of the interaction between internal and Stokes surface waves is considered. An internal wave (IW) is set in the form of a large-scale variable surface flow, directed at a certain angle to the surface-wave (SW) field. Wave interaction patterns are studied, and a comparison with the results of linear modulation model is performed. The dependence of the refraction-wave pattern on the main parameters of the problem (SW steepness, strength and direction of IW-induced flow, and the angle between the SW and IW) is investigated.     

Pattern formation in a reaction-diffusion-advection system with wave instability

In this paper, we show by means of numerical simulations how new patterns can emerge in a system with wave instability when a unidirectional advective flow (plug flow) is added to the system. First, we introduce a three variable model with one activator and two inhibitors with similar kinetics to those of the Oregonator model of the Belousov-Zhabotinsky reaction. For this model, we explore the type of patterns that can be obtained without advection, and then explore the effect of different velocities of the advective flow for different patterns. We observe standing waves, and with flow there is a transition from out of phase oscillations between neighboring units to in-phase oscillations with a doubling in frequency. Also mixed and clustered states are generated at higher velocities of the advective flow. There is also a regime of "waving Turing patterns" (quasi-stationary structures that come close and separate periodically), where low advective flow is able to stabilize the stationary Turing pattern. At higher velocities, superposition and interaction of patterns are observed. For both types of patterns, at high velocities of the advective field, the known flow distributed oscillations are observed.