Heavy Particle Concentration in Turbulence at Dissipative and Inertial Scales

Bec, Jérémie; Biferale, Luca; Cencini, Massimo; Lanotte, Alessandra S.; Musacchio, Stefano; Toschi, Federico

doi:10.1103/physrevlett.98.084502

Cited by 314 publications

(373 citation statements)

References 21 publications

Supporting

Mentioning

330

Contrasting

Order By: Relevance

“…Previous studies have demonstrated that the trajectories of passive tracer particles integrated via this numerical scheme accurately capture both the velocity 46 and the acceleration 47 statistics of the underlying DNS-derived flow. Moreover, previous studies on clustering of inertial particles 48 have demonstrated the efficacy of this method to resolve sub-Kolmogorov scale fractal aggregations, which we also observed for gyrotactic swimmers.…”

Section: ã2supporting

confidence: 52%

Turbulence drives microscale patches of motile phytoplankton

et al. 2013

View full text Add to dashboard Cite

Patchiness plays a fundamental role in phytoplankton ecology by dictating the rate at which individual cells encounter each other and their predators. The distribution of motile phytoplankton species is often considerably more patchy than that of non-motile species at submetre length scales, yet the mechanism generating this patchiness has remained unknown. Here we show that strong patchiness at small scales occurs when motile phytoplankton are exposed to turbulent flow. We demonstrate experimentally that Heterosigma akashiwo forms striking patches within individual vortices and prove with a mathematical model that this patchiness results from the coupling between motility and shear. When implemented within a direct numerical simulation of turbulence, the model reveals that cell motility can prevail over turbulent dispersion to create strong fractal patchiness, where local phytoplankton concentrations are increased more than 10-fold. This 'unmixing' mechanism likely enhances ecological interactions in the plankton and offers mechanistic insights into how turbulence intensity impacts ecosystem productivity.

show abstract

Section: ã2supporting

confidence: 52%

Turbulence drives microscale patches of motile phytoplankton

et al. 2013

View full text Add to dashboard Cite

show abstract

“…Numerical studies [10,50] show that the qualitative St-dependence of D 2 is similar to that observed in the Kraichnan model. Despite such similarities, it is likely that in turbulence, ejection from vortical regions play, at least for small St, an important role [50]. This can clearly not be accounted for in Kraichnan flows, as δ-correlated flows have no persistent structures.…”

Section: Remarks and Conclusionmentioning

confidence: 62%

“…However, while in the Kraichnan case the particle distribution depends on the local Stokes number St(r) only, this does not seem to be the case in turbulence, at least for St(r) ≪ 1 as studied in [50] ( which in turbulence is defined by St(r) = τ /τ r , τ r being the characteristic turbulent time scale associated to the scale r). In turbulent flows, for small values of St(r), a different rescaling related to that of the acceleration (and hence pressure) field has been found [50]. However such discrepancies do not question the relevance of the Kraichnan model to turbulent flows as it is expected to be a good approximation only for scales r such that τ r ≪ τ , i.e.…”

Section: Remarks and Conclusionmentioning

confidence: 99%

Stochastic suspensions of heavy particles

Bec

Cencini

Hillerbrand

et al. 2008

Physica D: Nonlinear Phenomena

View full text Add to dashboard Cite

Turbulent suspensions of heavy particles in incompressible flows have gained much attention in recent years. A large amount of work focused on the impact that the inertia and the dissipative dynamics of the particles have on their dynamical and statistical properties. Substantial progress followed from the study of suspensions in model flows which, although much simpler, reproduce most of the important mechanisms observed in real turbulence. This paper presents recent developments made on the relative motion of a pair of particles suspended in time-uncorrelated and spatially self-similar Gaussian flows. This review is complemented by new results. By introducing a time-dependent Stokes number, it is demonstrated that inertial particle relative dispersion recovers asymptotically Richardson's diffusion associated to simple tracers. A perturbative (homogeneization) technique is used in the small-Stokes-number asymptotics and leads to interpreting first-order corrections to tracer dynamics in terms of an effective drift. This expansion implies that the correlation dimension deficit behaves linearly as a function of the Stokes number. The validity and the accuracy of this prediction is confirmed by numerical simulations.

show abstract

“…For values of St not too large, the RDF for a monodisperse system typically takes the form of a power law which reflects the multi-scale self-similar nature of droplet clustering (e.g. Figures 7 and 8 of Goto and Vassilicos, 2006;Bec, 2005;Bec et al, 2007). This multi-scale clustering has been accounted for in terms of the sweep-stick mechanism, which explains why droplet clustering mimics the multi-scale clustering of vanishing fluid acceleration points in a turbulent flow (Coleman and Vassilicos, 2009).…”

Section: Droplet Clusteringmentioning

confidence: 99%

Droplet growth in warm turbulent clouds

Devenish

Bartello

Brenguier

et al. 2012

Quart J Royal Meteoro Soc

238

280

View full text Add to dashboard Cite

In this survey we consider the impact of turbulence on cloud formation from the cloud scale to the droplet scale. We assess progress in understanding the effect of turbulence on the condensational and collisional growth of droplets and the effect of entrainment and mixing on the droplet spectrum. The increasing power of computers and better experimental and observational techniques allow for a much more detailed study of these processes than was hitherto possible. However, much of the research necessarily remains idealized and we argue that it is those studies which include such fundamental characteristics of clouds as droplet sedimentation and latent heating that are most relevant to clouds. Nevertheless, the large body of research over the last decade is beginning to allow tentative conclusions to be made. For example, it is unlikely that small-scale turbulent eddies (i.e. not the energy-containing eddies) alone are responsible for broadening the droplet size spectrum during the initial stage of droplet growth due to condensation. It is likely, though, that small-scale turbulence plays a significant role in the growth of droplets through collisions and coalescence. Moreover, it has been possible through detailed numerical simulations to assess the relative importance of different processes to the turbulent collision kernel and how this varies in the parameter space that is important to clouds. The focus of research on the role of turbulence in condensational and collisional growth has tended to ignore the effect of entrainment and mixing and it is arguable that they play at least as important a role in the evolution of the droplet spectrum. We consider the role of turbulence in the mixing of dry and cloudy air, methods of quantifying this mixing and the effect that it has on the droplet spectrum. Copyright

show abstract

Heavy Particle Concentration in Turbulence at Dissipative and Inertial Scales

Cited by 314 publications

References 21 publications

Turbulence drives microscale patches of motile phytoplankton

Turbulence drives microscale patches of motile phytoplankton

Stochastic suspensions of heavy particles

Droplet growth in warm turbulent clouds

Contact Info

Product

Resources

About