Dispersion of finite-size particles probing inhomogeneous and anisotropic turbulence

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Mériaux, C. A., Teixeira, M. A. C. ORCID: https://orcid.org/0000-0003-1205-3233, Monaghan, J. J., Cohen, R. and Cleary, P. (2020) Dispersion of finite-size particles probing inhomogeneous and anisotropic turbulence. European Journal of Mechanics & Fluids - B/Fluids, 84. pp. 93-109. ISSN 0997-7546 doi: 10.1016/j.euromechflu.2020.05.015

Abstract/Summary

A series of 8 laboratory experiments was used to investigate the dynamics of a few almost neutrally-buoyant finite-size particles in the entire volume of a rectangular tank open to air and filled with water. Stirring was achieved by a cylinder executing a two-dimensional periodic Lissajoux figure. The rate and direction of stirring by the cylinder was varied. The particle motions were analyzed using a tracking method developed for the experimental design. The Reynolds number associated with the large-scale stirring motion was in a turbulent range of [5,693-11,649] across all experiments. The absence of stirring in the direction of the cylinder axis, the constant interference of the cylinder with the eddies and the presence of walls and the free-surface resulted in a flow that was both inhomogeneous and anisotropic as recorded by the particle motion. Despite these unusual conditions, the single-particle dispersion across all experiments could be seen to follow a ballistic regime until about two-fifths of the particle Lagrangian velocity auto-correlation time T_L. It was followed by a brief diffusive regime between T_L and 2.5 T_L, after which the presence of the boundaries prevented further dispersion. Such evolution is consistent with classic predictions for fluid tracer dispersion in homogeneous and isotropic turbulence. Particle-pair dispersion was more complex. Both the fixed time-averaged and length-scale-dependent particle-pair dispersion rates averaged across pairs showed the ballistic dispersion regime, whereas the subsequent diffusive regime was better borne out by the length-scale-dependent particle-pair dispersion. A super-diffusive Richardson regime was not unmistakably detected. Substantial variability was however found across the different pairs of particles, which was linked to differences in the decorrelation time of the velocity difference as a result of the inhomogeneity of the turbulence. For short initial separations, some particle pairs had a better separation of the time scales delimiting the ballistic and diffusive regimes and showed hints of a brief Richardson regime.

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Item Type	Article
URI	https://reading-clone.eprints-hosting.org/id/eprint/90962
Item Type	Article
Refereed	Yes
Divisions	Science > School of Mathematical, Physical and Computational Sciences > Department of Meteorology
Uncontrolled Keywords	Turbulence, Dispersion, Particle mixing, Experimental modelling
Publisher	Elsevier
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Date Deposited:	03 Jun 2020 15:45	Date item deposited into CentAUR
Last Modified:	25 Jan 2025 00:19	Date item last modified

References

Aurell, E., Boffetta, G., Crisanti, A., Paladin, G., Vulpiani, A., 1996. Growth of noninfinitesimal perturbations in turbulence. Physical Review Letters, 77, 1262. Balachandar, S., Eaton, J. K., 2010. Turbulent dispersed multiphase flow. Annual review of Fluid Mechanics, 42, 111-133. Batchelor, G., 1950. The application of the similarity theory of turbulence to atmospheric diffusion. Quarterly Journal of the Royal Meteorological Society, 76, 133-146. Bellani, G., Byron, M. L., Collignon, A. G., Meyer, C. R., Variano, E. A., 2012. Shape effects on turbulent modulation by large nearly neutrally buoyant particles. Journal of Fluid Mechanics, 712, 41-60. Biferale, L., Bodenschatz, E., Cencini, M., Lanotte, A. S., Ouellette, N. T., Toschi, F., Xu, H., 2008. Lagrangian structure functions in turbulence: A quantitative comparison between experiment and direct numerical simulation. Physics of Fluids, 20, 065103. Bitane, R., Homann, H., Bec, J., 2012. Time scales of turbulent relative dispersion. Physical Review E, 86, 045302. Boffetta, G., Cencini, M., Espa, S., Querzoli, G., 2000. Chaotic advection and relative dispersion in an experimental convective flow. Physics of Fluids, 12, 3160-3167. Boffetta, G., Sokolov, I., 2002. Relative dispersion in fully developed turbulence: the richardson's law and intermittency corrections. Physical Review Letters, 88, 094501. Bourgoin, M., 2015. Turbulent pair dispersion as a ballistic cascade phenomenology. Journal of Fluid Mechanics 772, 678-704. Bourgoin, M., Qureshi, N. M., Baudet, C., Cartellier, A., Gagne, C., 2011. Turbulent transport of finite sized material particles. In: Journal of Physics: Conference Series. Vol. 318. IOP Publishing, p. 012005. Corrado, R., Lacorata, G., Palatella, L., Santoleri, R., Zambianchi, E., 2017. General characteristics of relative dispersion in the ocean. Scientific Reports, 7, 46291. Csanady, G. T., 1973. The fluctuation problem in turbulent diffusion. In: Turbulent Diffusion in the Environment. Springer, pp. 222-248. Einstein, A., 1956. Investigations on the Theory of the Brownian Movement. Courier Corporation. Fiabane, L., Zimmermann, R., Volk, R., Pinton, J.-F., Bourgoin, M., 2012. Clustering of finite-size particles in turbulence. Physical Review E, 86, 035301. Gibert, M., Xu, H., Bodenschatz, E., 2010. Inertial effects on two-particle relative dispersion in turbulent flows. EPL (Europhysics Letters), 90, 64005. Gore, R., Crowe, C. T., 1989. Effect of particle size on modulating turbulent intensity. International Journal of Multiphase Flow, 15, 279-285. Ibrahim, R. A., 2005. Liquid sloshing dynamics: theory and applications. Cambridge University Press. Klein, S., Gibert, M., Berut, A., Bodenschatz, E., 2012. Simultaneous 3D measurement of the translation and rotation of finite-size particles and the flow field in a fully developed turbulent water flow. Measurement Science and Technology, 24, 024006. Kolmogorov, A. N., 1941a. Energy dissipation in locally isotropic turbulence. In: Dokl. Akad. Nauk. SSSR. Vol. 32. pp. 19-21. Kolmogorov, A. N., 1941b. The local structure of turbulence in incompressible viscous fluid for very large Reynolds numbers. In: Dokl. Akad. Nauk SSSR. Vol. 30. pp. 299-303. La Porta, A., Voth, G. A., Crawford, A. M., Alexander, J., Bodenschatz, E., 2001. Fluid particle accelerations in fully developed turbulence. Nature, 409, 1017. Machicoane, N., Volk, R., 2016. Lagrangian velocity and acceleration correlations of large inertial particles in a closed turbulent flow. Physics of Fluids, 28, 035113. Monaghan, J., 2017. SPH-E simulation of 2D turbulence driven by a moving cylinder. European Journal of Mechanics-B/Fluids, 65, 486-493. Monaghan, J., Meriaux, C. A., 2018a. An SPH study of driven turbulence near a free surface in a tank under gravity. European Journal of Mechanics-B/Fluids, 68, 201-210. Monaghan, J., Meriaux, C. A., 2018b. What can we learn from large bodies moving in a turbulent fluid? European Journal of Mechanics-B/Fluids, 72, 519-530. Monin, Andrei, S., Yaglom, A. M., 2013. Statistical fluid mechanics, volume 744 II: Mechanics of Turbulence. Vol. 2. Courier Corporation. Mordant, N., Delour, J., Leveque, E., Michel, O., Arneodo, A., Pinton, J.-F., 2003. Lagrangian velocity fluctuations in fully developed turbulence: scaling, intermittency, and dynamics. Journal of Statistical Physics, 113, 701-717. Mordant, N., Leveque, E., Pinton, J.-F., 2004. Experimental and numerical study of the Lagrangian dynamics of high Reynolds turbulence. New Journal of Physics, 6, 116. Ouellette, N. T., Xu, H., Bourgoin, M., Bodenschatz, E., 2006. Small-scale anisotropy in lagrangian turbulence. New Journal of Physics, 8, 102. Qureshi, N. M., Bourgoin, M., Baudet, C., Cartellier, A., Gagne, Y., 2007. Turbulent transport of material particles: an experimental study of finite-size effects. Physical Review Letters, 99, 184502. Richardson, L. F., 1926. Atmospheric diffusion shown on a distance-neighbour graph. Proc. R. Soc. Lond. A, 110, 709-737. Salazar, J. P., Collins, L. R., 2009. Two-particle dispersion in isotropic turbulent flows. Annual Review of Fluid Mechanics, 41, 405-432. Sreenivasan, K. R., 1995. On the universality of the Kolmogorov constant. Physics of Fluids, 7, 2778-2784. Taylor, G. I., 1922. Diffusion by continuous movements. Proceedings of the London Mathematical Society, 2, 196-212. Teixeira, M., Belcher, S., 2000. Dissipation of shear-free turbulence near boundaries. Journal of Fluid Mechanics, 422, 167-191. Toschi, F., Bodenschatz, E., 2009. Lagrangian properties of particles in turbulence. Annual Review of Fluid Mechanics, 41, 375-404. Valizadeh, A., Monaghan, J., 2015. SPH simulation of 2D turbulence driven by a cylindrical stirrer. European Journal of Mechanics-B/Fluids, 51, 44-53. Valizadeh, A., Monaghan, J. J., 2012. Smoothed particle hydrodynamics simulations of turbulence in fixed and rotating boxes in two dimensions with no-slip boundaries. Physics of Fluids, 24, 035107. Vargaftik, N., Volkov, B., Voljak, L., 1983. International tables of the surface tension of water. Journal of Physical and Chemical Reference Data, 12, 817-820. Volk, R., Calzavarini, E., Leveque, E., Pinton, J.-F., 2011. Dynamics of inertial particles in a turbulent von Karman flow. Journal of Fluid Mechanics, 668, 223-235. Xia, H., Francois, N., Faber, B., Punzmann, H., Shats, M., 2019. Local anisotropy of laboratory two-dimensional turbulence affects pair dispersion. Physics of Fluids, 31, 025111. Yeung, P., Pope, S., 1988. An algorithm for tracking fluid particles in numerical simulations of homogeneous turbulence. Journal of Computational Physics, 79, 373-416. Zandbergen, P., Dijkstra, D., 1987. Von ka�rma�n swirling ows. Annual Review of Fluid Mechanics, 19, 465-491. Zimmermann, R., Gasteuil, Y., Bourgoin, M., Volk, R., Pumir, A., Pinton, J.-F., for Turbulence, I. C., 2011. Tracking the dynamics of translation and absolute orientation of a sphere in a turbulent flow. Review of Scientific Instruments, 82, 033906.

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