SPECTRA OF FLUCTUATIONS OF VELOCITY, KINETIC-ENERGY, AND THE DISSIPATION RATE IN STRONG TURBULENCE

被引:5
|
作者
YAKHOT, V
机构
[1] Program in Applied and Computational Mathematics, Princeton University, Princeton
来源
PHYSICAL REVIEW E | 1994年 / 50卷 / 01期
关键词
D O I
10.1103/PhysRevE.50.R20
中图分类号
O35 [流体力学]; O53 [等离子体物理学];
学科分类号
070204 ; 080103 ; 080704 ;
摘要
Following the ideas of operator product expansion, the velocity v, kinetic energy K = 1/2upsilon2, and dissipation rate epsilon=nu0(partial derivativeupsilon(i)/partial derivativex(j))2 are treated as independent dynamical variables, each obeying its own equation of motion. The relations DELTAu(DELTAK)2BAR is-proportional-to r, DELTAU(DELTAepsilon)2BAR is-proportional-to r0, and (DELTAu)5BAR almost-equal-to rDELTAepsilonDELTAK are derived. If velocity scales as (DELTAupsilon)rms is-proportional-to r(gamma/3)-1, then simple power counting gives (DELTAK)rms is-proportional-to r1-(gamma/6) and (DELTAepsilon)rms is-proportional-to 1/square-root (DELTAupsilon)rms is-proportional-to r(1/2)-(gamma/6). In the Kolmogorov turbulence (gamma=4) the intermittency exponent mu = (gamma/3)-1 = 1/3 and (DELTAepsilon)2=O(Re1/4). The scaling relation for the epsilon fluctuations is a consequence of cancellation of ultraviolet divergences in the equation of motion for the dissipation rate.
引用
收藏
页码:R20 / R23
页数:4
相关论文
共 50 条
  • [21] EFFECT OF DISSIPATION FLUCTUATIONS ON ANOMALOUS VELOCITY SCALING IN TURBULENCE
    EGGERS, J
    GROSSMANN, S
    PHYSICAL REVIEW A, 1992, 45 (04) : 2360 - 2369
  • [22] A BULK PBL MODEL WITH NONSTATIONARY EQUATIONS FOR THE TURBULENT KINETIC-ENERGY AND ITS DISSIPATION RATE
    DEMCHENKO, PF
    IZVESTIYA AKADEMII NAUK FIZIKA ATMOSFERY I OKEANA, 1993, 29 (03): : 315 - 320
  • [23] POWER SPECTRA OF FLUCTUATIONS IN STRONG LANGMUIR TURBULENCE
    DUBOIS, DF
    ROSE, HA
    RUSSELL, D
    PHYSICAL REVIEW LETTERS, 1988, 61 (19) : 2209 - 2212
  • [24] DOPPLER RADAR MEASUREMENTS OF TURBULENT KINETIC-ENERGY DISSIPATION RATE IN A NORTHEAST COLORADO THUNDERSTORM
    FRISCH, AS
    STRAUCH, RG
    TRANSACTIONS-AMERICAN GEOPHYSICAL UNION, 1975, 56 (12): : 986 - 987
  • [25] A MEMS flow velocity sensor with low kinetic energy dissipation rate
    Tian, Bian
    Li, Huafeng
    Yang, Ning
    Zhao, Yulong
    Chen, Pei
    Liu, Hanyue
    SENSOR REVIEW, 2017, 37 (03) : 247 - 256
  • [26] THE DISSIPATION OF KINETIC-ENERGY IN A WARM-CORE RING
    LUECK, R
    OSBORN, T
    JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS, 1986, 91 (C1): : 803 - 818
  • [27] DISSIPATION EFFECT OF KINETIC-ENERGY IN A FREELY SPINNING TOP
    KROTOV, VV
    ZHURNAL TEKHNICHESKOI FIZIKI, 1988, 58 (08): : 1581 - 1583
  • [28] An Algorithm of Calculating Turbulence Kinetic Energy Dissipation Rate Based on Motion Compensation
    Wang, Yongfang
    Qiu, Jianlong
    Li, Tongxing
    Luan, Xin
    Song, Dalei
    2015 5TH INTERNATIONAL CONFERENCE ON INFORMATION SCIENCE AND TECHNOLOGY (ICIST), 2015, : 579 - 582
  • [29] VELOCITY PROFILES, THE RESISTANCE LAW AND THE DISSIPATION RATE OF MEAN FLOW KINETIC-ENERGY IN A NEUTRALLY AND STABLY STRATIFIED PLANETARY BOUNDARY-LAYER
    ZILITINKEVICH, SS
    BOUNDARY-LAYER METEOROLOGY, 1989, 46 (04) : 367 - 387
  • [30] KINETIC-ENERGY SPECTRA OF DIVERGENT WIND IN THE ATMOSPHERE
    CHEN, TC
    TRIBBIA, JJ
    TELLUS, 1981, 33 (01): : 102 - 104
12345