Transverse velocity increments in turbulent flow using the RELIEF technique

A. NOULLEZ; G. WALLACE; W. LEMPERT; R. B. MILES; U. FRISCH

doi:10.1017/S0022112097005338

Abstract

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Non-intrusive measurements of the streamwise velocity in turbulent round jets in air are performed by recording short-time displacements and distorsions of very thin tagging lines written spanwise into the flow. The lines are written by Raman-exciting oxygen molecules and are interrogated by laser-induced electronic fluorescence (relief). This gives access to the spatial structure of transverse velocity increments without recourse to the Taylor hypothesis. The resolution is around 25 μm, less than twice the Kolmogorov scale η for the experiments performed (with Rλ≈360–600).

The technique is validated by comparison with results obtained from other techniques for longitudinal or transverse structure functions up to order 8. The agreement is consistent with the estimated errors – a few percent on exponents determined by extended-self-similarity – and indicates significant departures from Kolmogorov (1941) scaling.

Probability distribution functions of transverse velocity increments Δu over separations down to 1:8η are reported for the first time. Violent events, with Δu comparable to the r.m.s. turbulent velocity fluctuation, are found to take place with statistically significant probabilities. The shapes of the corresponding lines suggest the effect of intense slender vortex filaments.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Chen, Shiyi Sreenivasan, Katepalli R. Nelkin, Mark and Cao, Nianzheng 1997. Refined Similarity Hypothesis for Transverse Structure Functions in Fluid Turbulence. Physical Review Letters, Vol. 79, Issue. 12, p. 2253.

Falkovich, G. and Lebedev, V. 1997. Single-Point Velocity Distribution in Turbulence. Physical Review Letters, Vol. 79, Issue. 21, p. 4159.

Antonia, R. A and Pearson, B. R 1997. Scaling exponents for turbulent velocity and temperature increments. Europhysics Letters (EPL), Vol. 40, Issue. 2, p. 123.

She, Zhen-Su 1997. Turbulence Modeling and Vortex Dynamics. Vol. 491, Issue. , p. 28.

Vainshtein, Samuel I. 1997. Probing asymmetry and self-similarity of fully developed turbulence. Physical Review E, Vol. 56, Issue. 6, p. 6787.

Grossmann, Siegfried Lohse, Detlef and Reeh, Achim 1997. Different intermittency for longitudinal and transversal turbulent fluctuations. Physics of Fluids, Vol. 9, Issue. 12, p. 3817.

Dhruva, Brindesh Tsuji, Yoshiyuki and Sreenivasan, Katepalli R. 1997. Transverse structure functions in high-Reynolds-number turbulence. Physical Review E, Vol. 56, Issue. 5, p. R4928.

Rastegar, A.R. Rahimi Tabar, M.R. and Hawaii, P. 1998. Exact two-point correlation functions of turbulence without pressure in three dimensions. Physics Letters A, Vol. 245, Issue. 5, p. 425.

Arad, Itai Dhruva, Brindesh Kurien, Susan L'vov, Victor S. Procaccia, Itamar and Sreenivasan, K. R. 1998. Extraction of Anisotropic Contributions in Turbulent Flows. Physical Review Letters, Vol. 81, Issue. 24, p. 5330.

Noullez, A. Frisch, U. Wallace, G. Lempert, W. and Miles, R. B. 1998. Advances in Turbulence VII. Vol. 46, Issue. , p. 51.

Baudet, C. and Michel, O. 1998. Advances in Turbulence VII. Vol. 46, Issue. , p. 43.

She, Zhen-Su 1998. Flow at Ultra-High Reynolds and Rayleigh Numbers. p. 391.

Zheltikov, A.M. Akimov, D.A. Fedotov, A.B. Koroteev, N.I. Miles, R.B. Naumov, A.N. and Sidorov-Biyukov, D.A. 1998. Nonlinear-optical imaging and tagging of atoms and molecules in plasmas and gas flows. p. 147.

Jiménez, J. 1998. Small scale intermittency in turbulence. European Journal of Mechanics - B/Fluids, Vol. 17, Issue. 4, p. 405.

Goldburg, W.I. Belmonte, A. Wu, X.L. and Zusman, I. 1998. Flowing soap films: a laboratory for studying two-dimensional hydrodynamics. Physica A: Statistical Mechanics and its Applications, Vol. 254, Issue. 1-2, p. 231.

Tsinober, A. 1998. Chaos, Kinetics and Nonlinear Dynamics in Fluids and Plasmas. Vol. 511, Issue. , p. 83.

Minotti, F.O. and Ferro Fontán, C. 1998. Navier-stokes probability density function. European Journal of Mechanics - B/Fluids, Vol. 17, Issue. 4, p. 505.

Voth, Greg A. Satyanarayan, K. and Bodenschatz, Eberhard 1998. Lagrangian acceleration measurements at large Reynolds numbers. Physics of Fluids, Vol. 10, Issue. 9, p. 2268.

Vainshtein, S. I. 1998. Refined similarity hypothesis and asymmetry of turbulence. Physical Review E, Vol. 58, Issue. 2, p. 1851.

Yakhot, Victor 1998. Probability density and scaling exponents of the moments of longitudinal velocity difference in strong turbulence. Physical Review E, Vol. 57, Issue. 2, p. 1737.

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Transverse velocity increments in turbulent flow using the RELIEF technique

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