帮助 关于我们

返回检索结果

浮区热毛细对流
THERMOCAPILLARY CONVECTION IN FLOATING ZONES

查看参考文献93篇

文摘 概述了浮区中平行于自由面的表面张力梯度驱动热毛细对流领域的研究.研究兴趣集中于振荡热毛细对流的起振,或者说从定常流动到振荡流动的转捩.起振依赖于一系列的临界参数,临界关系可以表示为这些临界参数的复杂函数.实验结果表明,振荡流中速度的变化和平均流动的速度有相同的量级,而其它量的变化,比如温度和自由面半径的波动,相比于它们的平均量而言则要小得多.因此,起振应是流体中动力学过程的结果,该问题是强非线性的.在过去几十年中,一些理论模型被引入米研究这个问题,使用的方法包括理论分析方法、线性不稳定性分析方法、能量稳定性分析方法以及非定常的三维直接数值模拟.其中直接数值模拟被认为是对强非线性过程进行深入分析的最适合方法,通常能得到和实验较符合的结果.从振荡热毛细对流向湍流的转捩提供了一个研究混沌行为的新系统,开创了一个非线性科学的新前沿,是一个集中了大量近期工作的研究热点.该文对浮区热毛细对流作了一个回顾,包括理论模型和分析,以及实验研究.
其他语种文摘 This paper provides an overview of ongoing studies in the area of thermocapillary convection driven by a surface tension gradient parallel to the free surface in a floating zone, with emphases focused around the onset of oscillatory thennocapillary convection, also known as the transition from quasisteady convection to oscillatory convection. The onset of oscillation depends on a set of critical parameters, and the margin relationship can be represented by a complex function of the critical parameters. The experimental results indicate that the velocity deviation of an oscillatory flow has the same order of magnitude as that of an average flow, and the deviations of other quantities, such as temperature and free surface radii fluctuations, are much smaller when compared with their normal counterparts. Therefore, the onset of oscillation should be a result of the dynamic process in a fluid, and the problem is a strongly nonlinear one. In the past few decades, several theoretical models have been introduced to tackle the problem using analytical methods, linear instability analysis methods, energy instability methods, and unsteady 3D numerical methods, the last of which is known to be the most suitable for a thorough analysis of strong nonlinear processes, resulting generally in a better agreement with the experimental results. The transition from oscillatory thermocapillary convection to turbulence falls under the studies of chaotic behavior in a new system, which opens a fascinating new frontier in nonlinear science, a hot research area drawing many recent works. This paper, with 93 references cited, reviews theoretical models and analyses as well as experimental studies on thennocapillary connection in floating zones.
来源 力学进展 ,2009,39(3):360-377 【核心库】
关键词 浮区 ; 热毛细对流 ; 转捩 ; 稳定性
地址

中国科学院力学研究所, 中国科学院微重力重点实验室, 北京, 100190

语种 中文
文献类型 研究性论文
ISSN 1000-0992
学科 力学
基金 国家自然科学基金
文献收藏号 CSCD:3753013

参考文献 共 93 共5页

1.  Ostrach S. Low-grsvity fluid flow. Annual Review of Fluid Mechanics,1982,14:313-345 被引 10    
2.  Walter H U. Space Fluid Science and Materials Science,1987 被引 1    
3.  Ratke L. Materials and Fluids under Low Gravity:Proceedings of the IX European Symposium on Gravity-Dependent Phenomena in Physical Sciences,1996 被引 1    
4.  Jones L E. Interface Instability,2002 被引 1    
5.  Pearson J R A. On convection cells induced by surface tension. Journal of Fluid Mechanics,1958,4:489-500 被引 31    
6.  Xiong B. Crystal growth in floating zone with phase change and thermo-solutal convection. Journal of Crystal Growth,1992,125:149-156 被引 2    
7.  Chang C E. Inhomogeneities due to thermocapillary flow in floating zone melting. Journal of Crystal Growth,1975,28:8-12 被引 9    
8.  Chun Ch H. A micro-gravity simulation of the Marangoni convection. Acta Astronautica,1978,5:681-686 被引 5    
9.  Chun Ch H. Experiments on the transition from the steady to the oscillatory Marangoui-convection of a floating zone under reduced gravity effect. Acta Astronautica,1979,6:1073-1082 被引 10    
10.  Schwabe D. Experiments on surface tension driven flow in floating zone melting. Journal of Crystal Growth,1978,43:305-312 被引 8    
11.  Schwabe D. Some evidence for the existence and magnitude of a critical Marangoui number for the onset of oscillatory flow in crystal growth melts. Journal of Crystal Growth,1979,46:125-131 被引 4    
12.  Kuhlamann H C. Thermpcapillary Convection in Model of Crystal Growth,1999 被引 1    
13.  Hu W R. Floating Zone Convection,2003 被引 1    
14.  Levenstam M. Instabilities of thermocapillary convection in a half-zone at intermediate Prandtl numbers. Physics of Fluids,2001,13:807-816 被引 2    
15.  Preisser F. Steady and oscillatory thermocapillary convection in liquid columns with free cylindrical surface. Journal of Fluid Mechanics,1983,126:545-555 被引 5    
16.  Hu W R. Influence of liquid bridge volume on the onset of oscillation in floating zone convection I.Experiment. Journal of Crystal Growth,1994,142:379-386 被引 4    
17.  Tang Z M. Hu W 1% Influence of liquid bridge volume on the onset of oscillation in floating zone convection ⅡNumerical Simulations. J Crystal Growth,1994,142:385-391 被引 2    
18.  Levenstam M. Hydrodynamical instabilities of thermocapillary flow in a half zone. Journal of Fluid Mechanics,1995,297:357-372 被引 11    
19.  Nakamura S. Observation of periodic Marangoni convection in a molten silicon bridge on board the TR-IA-6 rocket. J Jpn Soc Microgravity Appl,1999,16:99-103 被引 1    
20.  Chang Y K. The float-zone growth of Ti3Au and Ti3Pt. J Crystal Growth,1983,62:627-632 被引 2    
引证文献 1

1 姜欢 矩形液池热毛细对流转捩途径研究 力学学报,2015,47(3):422-429
被引 1

显示所有1篇文献

论文科学数据集
PlumX Metrics
相关文献

 作者相关
 关键词相关
 参考文献相关

iAuthor 链接
李凯 0000-0002-3943-4602
版权所有 ©2008 中国科学院文献情报中心 制作维护:中国科学院文献情报中心
地址:北京中关村北四环西路33号 邮政编码:100190 联系电话:(010)82627496 E-mail:cscd@mail.las.ac.cn 京ICP备05002861号-4 | 京公网安备11010802043238号