固-固接触热传导的声子传递系数

声子传递系数是影响低温接触界面热传导的重要因素,文中对中间低温(20K~200K)接触传导模型的声子传递系数进行了讨论,分析了接触界面温差、弹性镜面传递和散射传递下的声子传递系数;还讨论了热流方向对声子传递系数的影响;指出了声失配理论预测值与实验值间存在差别的可能原因。该讨论对分析接触热传导有一定意义。     

HL-2M 环向场线圈水冷数值模拟与分析

建立了环向场线圈的水冷计算模型,根据热传导和对流换热方程进行了数值模拟分析。计算结果表明：指形接头与铜板的界面接触热阻和接触电阻对指形接头的温升影响较大,但在平顶电流为140kA 及其电流平顶7s 时,由焦耳热引起的最高温升40℃以下,故环向场线圈的温度均不会超过80℃,且15min 后TF 线圈温度均降至30℃以下。在平顶电流为190kA 时,线圈通电持续时间可根据界面实测接触热阻、接触电阻以及线圈初始温度来确定。     

二极管端面抽运固体激光器晶体棒与热沉接触热导研究

二极管端面抽运固体激光器中,圆棒晶体采用金属热沉夹持并散热,晶体侧面受到的压力呈非轴对称分布.建立了此状态下晶体棒与热沉间无热界面物质、采用厚度为平均间隙厚度和远大于平均间隙厚度的热界面物质三种情况下接触热导模型.针对前两种模型,采用截断高斯模型和塑性形变模型,讨论了接触热导与装配压力、等效均方根粗糙度的关系.建立了晶体棒与热沉的接触散热模型,对高斯型热耗分布,采用有限元法得到了无热界面物质和采用铟箔作为热界面物质时晶体棒温度的空间分布.结果表明:无热界面物质时,晶体棒与热沉间接触热导随圆心角变化较大,其 关键词： 激光二极管端面抽运固体激光器 热效应 有限元法 接触热导     

考虑界面接触热阻的一维复合结构的热整流机理

建立了考虑变截面、变热导率及界面接触热阻效应的组合热整流结构的温度场及热整流系数的理论模型和有限元解.数值算例证明了本文模型及算法的可靠性,进而通过参数影响研究确定了若干几何及材料参数对结构热整流系数的影响规律,揭示界面接触热阻对热整流效果的影响机理.研究结果表明长度比、截面半径变化率、热导率、边界条件温差和界面接触热阻等因素必须通过优化设计才能得到最大的热整流系数,同时界面接触热阻的引入也为调控热整流系数提供了一条新的途径.     

用分形理论研究低温条件下Al-Al界面间的接触导热现象

界面形貌是固体界面间接触导热的最主要影响因素 ,传统的形貌表征参数与仪器的分辨率和取样长度密切相关 ,因而基于这些参数的常规接触导热模型显然是尺度相关的。分形网络模型利用粗糙表面处处连续却不可微的分形特征 ,采用与尺度无关的分形参数 ,揭示了接触导热的本质 ,为准确预测接触热导开辟了一条新的途径。实验测定了粗糙表面的分形参数和低温条件下 Al50 52 - Al50 52界面间的接触热导 ,将接触热导的实验值与分形网络模型的预测结果进行了比较 ,并就接触热导与压力、分形参数和温度之间的关系进行了分析 ,指出分形网络模型的预测精度与分形参数相关联。     

平衡接触角对受热液滴在水平壁面上铺展特性的影响

壁面温度是影响壁面润湿性的重要外部条件. 为解决液滴铺展中三相接触线处应力集中问题, 已有研究多采用预置液膜假设, 但无法探究壁面温度对润湿性的影响. 本文针对受热液滴在固体壁面上的铺展过程, 基于润滑理论建立了演化模型, 通过数值模拟, 从平衡接触角角度分析了温度影响壁面润湿性及铺展过程的内部机理. 研究表明: 随温度梯度增大, 液滴所受Marangoni效应增强, 致使液滴向低温区的铺展速率加快; 铺展过程中, 位于高温区的接触线与液滴主体部分间形成一层薄液膜, 重力与热毛细力先后主导该区域的铺展; 当液-固或气-液界面张力对温度的敏感度高于另两个界面时, 低温区方向的平衡接触角不断增大, 使壁面润湿性恶化, 导致液滴铺展减慢; 而当气-固界面张力对温度的敏感度高于其他两个界面时, 低温区方向上的平衡接触角将减小, 由此改善壁面润湿性, 加快液滴铺展; 在温度影响壁面润湿性和液滴铺展过程中, 平衡接触角起关键作用.     

低温下粗糙表面接触间隙气体热导的研究

对低温非真空环境下粗糙接触界面间隙中介质气体的传热进行了理论分析．依据克努森数的大小,建立了不同传热区域的间隙气体热导理论模型．并对影响接触界面间隙热导的克努森数、普朗特数、热导率、适应系数、压力等参数进行了分析,为实际情况下接触界面的传热提供了理论基础．而且通过实验证明了在界面接触压力较小的情况下,即使对于硬度较小导热性能好的接触固体,间隙气体的导热量仍大于通过实际接触点的导热量．     

双层薄膜界面声子输运的Monte Carlo模拟

界面声子热输运现象广泛地存在于纳米热电装置和微纳电子器件中,但其物理机制和介观模型仍不完善。本文将考虑真实色散关系的漫射失配(DMM)界面模型引入到高效、低噪的动力型声子Monte Carlo(MC)方法,建立了一个频谱穿透系数的界面声子输运数值模型。采用新的数值模型研究了室温下Si/Al薄膜中的界面声子输运,可准确捕捉法向输运和面向输运的非平衡效应。     

反复加载情况下低温固体界面间接触导热的研究

文中从固体界面间接触热阻形成机理出发,提出了一种强化接触导热的方法,给出了低温真空环境下,两种金属界面间在反复加载情况下的接触热阻值,对卸载过程接触热导率大于同次加载过程接触热导的实验现象产生机理进行了分析,并指出了下一步的研究方向     

方腔内相变材料固液相变传热研究

基于相变材料(PCM,phase change material)的相变储能设备具有储能密度高的特点。本文建立了基于相变储能元件伪焓模型的固液相变格子Boltzmann模型,研究了内部管道位置、方腔倾斜角度对PCM融化过程的影响规律。结果表明,在内管道靠近方腔上部时,由于上部界面(固液相变界面或上壁面)对自然对流阻碍作用,使PCM的融化速率减慢。但是,在此时使方腔发生倾斜,会改变管道热流体到上部界面的距离,强化PCM的热质传递过程,使融化加快。     

微结构接触界面热阻

微纳米结构的接触热传输是热电转换、超导冷却、集成芯片散热等高技术领域面临并必须着力解决的技术问题,它区别于宏观热传输,具有为尺度依赖效应和多个微观特征量。文中从微结构接触热传输阻力角度出发,探讨了接触热阻及界面热阻区别,阐释了微尺度的特征量,接触界面热阻实验及理论研究方法、实验参数的测量,接触热阻及界面热阻的材料选择。通过接触界面热阻这些方面的研究,为研究接触界面热阻研究提供了较全面的参考。     

Effects of contact shape on ballistic phonon transport in semiconductor nanowires

We study the effects of contact shape on ballistic phonon transport in semiconductor nanowires at low temperatures using an approximative scalar model of continuum elasticity. Five different contacts connected to two semiconductor nanowires with different transverse widths are discussed. Numerical results show that the contact shape acts as an ‘acoustic impedance adaptor’, playing a crucial role on the ballistic phonon transmission and thermal conductance. The phonon coupling in the contacts with certain length facilitates ballistic phonon transmission compared to the abrupt interface, in which the phonon scattering is the strongest. It is found that the more the contact is abrupt, the smaller the thermal conductance is. The catenoidal contact rather than the abrupt interface is also the competitive candidate to obtain bigger thermal conductance. These results indicate that choosing an appropriate contact shape is one of the most critical factors to accurately measure the thermal conductance with a very high precision and reliability in different temperature ranges at low temperatures.     

Stiffness evaluation of contacting surfaces by bulk and interface waves

This paper describes ultrasonic measurements of normal and tangential stiffnesses of the contacting interface between polished aluminum blocks subjected to nominal contact pressures up to about 3.8 MPa. These stiffnesses were evaluated by ultrasonic spectroscopy methods for the bulk (longitudinal and transverse) wave reflection coefficients and the anti-symmetric mode interface wave velocity. The measurements revealed the interfacial stiffnesses as functions of the frequency as well as the applied contact pressure. The ratio of the tangential and normal stiffnesses is discussed in the light of foregoing theoretical and experimental findings. Furthermore, possible explanations for the frequency dependence of the measured stiffnesses are reviewed, invoking the spatial inhomogeneity of the interfacial stiffness as well as its lossy nature.     

强流脉冲下重复滑动电接触界面的电热特性

固体电枢电磁轨道发射中,膛内枢轨滑动电接触的电热特性关系到滑动界面的接触状态、电流传导品质和界面能量耗散,制约着系统效率和轨道寿命。设计开展了多组不同电流线密度的多发重复试验,通过采集电气试验数据进行迭代计算,得到了滑动接触电阻和界面焦耳热耗散功率的动态变化规律,分析了沉积物随重复发射的演变及电流线密度对电热特性的影响规律,并结合试验后轨道表面熔蚀沉积检测,讨论了滑动电接触界面的演变过程。结果表明：接触电阻稳定临界点和焦耳热耗散功率峰值点都出现在脉冲电流下降沿,接触电阻稳定值量级为10-2 m,焦耳热功率峰值幅值可达10-1 MW;炮口速度随重复次数的增加而降低并趋于稳定,多次重复发射对滑动接触电阻和焦耳热功率较小的影响表明沉积物在发射中再次熔融并对电接触起积极作用;而即使输入能量一致,电流线密度的变化也显著影响了界面焦耳热的生成。     

强流脉冲下重复滑动电接触界面的电热特性

固体电枢电磁轨道发射中,膛内枢轨滑动电接触的电热特性关系到滑动界面的接触状态、电流传导品质和界面能量耗散,制约着系统效率和轨道寿命。设计开展了多组不同电流线密度的多发重复试验,通过采集电气试验数据进行迭代计算,得到了滑动接触电阻和界面焦耳热耗散功率的动态变化规律,分析了沉积物随重复发射的演变及电流线密度对电热特性的影响规律,并结合试验后轨道表面熔蚀沉积检测,讨论了滑动电接触界面的演变过程。结果表明:接触电阻稳定临界点和焦耳热耗散功率峰值点都出现在脉冲电流下降沿,接触电阻稳定值量级为10-2 mΩ,焦耳热功率峰值幅值可达10-1 MW;炮口速度随重复次数的增加而降低并趋于稳定,多次重复发射对滑动接触电阻和焦耳热功率较小的影响表明沉积物在发射中再次熔融并对电接触起积极作用;而即使输入能量一致,电流线密度的变化也显著影响了界面焦耳热的生成。     

Stable electron field emission from carbon nanotubes emitter transferred on graphene films

Carbon nanotubes (CNTs) arrays grown by microwave plasma enhanced chemical vapor deposition (MPCVD) method was transferred onto the substrate covered with graphene layer obtained by thermal chemical vapor deposition (CVD) technology. The graphene buffer layer provides good electrical and thermal contact to the CNTs. The field emission characteristics of this hybrid structure were investigated in this study. Compared with the CNTs arrays directly grown on the silicon substrate, the hybrid emitter shows better field emission performance, such as high emission current and long-term emission stability. The presence of this graphene layer was shown to improve the field emission behavior of CNTs. This work provides an effective way to realize stable field emission from CNTs emitter and similar hybrid structures.     

Impact of Al addition on the formation of Ni germanosilicide layers under different temperature annealing

Solid reactions between Ni and relaxed Si_0.7Ge_0.3 substrate were systematically investigated with different Al interlayer thicknesses. The morphology, composition, and micro-structure of the Ni germanosilicide layers were analyzed with different annealing temperatures in the appearance of Al. The germanosilicide layers were characterized by Rutherford backscattering spectrometry, cross-section transmission electron microscopy, scan transmission electron microscopy, and secondary ion mass spectroscopy. It was shown that the incorporation of Al improved the surface and interface morphology of the germanosilicide layers, enhanced the thermal stabilities, and retarded the Ni-rich germanosilicide phase to mono germanosilicide phase. With increasing annealing temperature, Al atoms distributed from the Ni/Si_0.7Ge_0.3 interface to the total layer of Ni₂Si_0.7Ge_0.3, and finally accumulated at the surface of NiSi_0.7Ge_0.3. We found that under the assistance of Al atoms, the best quality Ni germanosilicide layer was achieved by annealing at 700 ℃ in the case of 3 nm Al.     

Picosecond time scale imaging of mechanical contacts

By means of an ultrafast opto-acoustic technique we study the nanoindentation of thin chromium films on sapphire substrates using a ceramic ball bearing. Acoustic pulses at ∼40 GHz returning from the film-indenter interface allow the film indentation profiles to be probed to sub-nanometer resolution over contact areas ∼25 μm in radius. The deformation of the films during loading is thereby revealed. Furthermore, thermal wave imaging of the contact at megahertz frequencies is simultaneously achieved.     

The thermal contact problem in nano- and micro-scale photothermal measurements

Thermal contact resistance between two solids is discussed with regard to its influence on the measurements of temperature and thermo-physical parameters in micro- and nano-structures. Two important applications are considered: thin film coatings on substrates and local measurements with a nano-probe in scanning thermal microscopy. The mechanical contact of a copper layer on carbon is measured by adhesion strength experiments and correlated to the thermal transport across the interface deduced from infrared radiometric measurements. A novel quantity the thermal wave contrast is introduced which takes into account the interface resistance and modifications of the coating and substrates at the interface. With regard to scanning thermal microscopy the contact resistance problem is discussed for 3ω-measurements in the active mode and for temperature measurements in the passive mode. It is shown that the thermo-elastic response can offer a means to avoid the influence of the thermal contact resistance on local temperature measurements.     

大气压力对激光辐照双层板接触传热的影响

考虑激光辐照下结构变形对双层板接触传热影响可以更真实地反映两板间的传热情况,通过实验和数值模拟分析了大气压力对接触传热的影响。结果表明:大气压力对接触热阻影响非常明显,当大气压力超过一定值后,双层板界面始终接触,后板中心的温升阶段成类抛物形状;当大气压力在某一范围内,大气压力与温度矩产生的靶板挠度相当,接触面时分时合,后板的温升阶段成振荡式类线性增加;当大气压力小于某一特定值时,后板温度有一突跃过程,通过适当的设计有可能观测到该现象。