Geometry of tracer trajectories in rotating turbulent flows

Alards, Kim M. J.; Rajaei, Hadi; Castello, Lorenzo Del; Kunnen, Rudie; Toschi, Federico; Clercx, Hjh Herman

doi:10.1103/physrevfluids.2.044601

Cited by 9 publications

(29 citation statements)

References 39 publications

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“…Figure 3(a,b) shows the autocorrelation of the velocity in the xy and z directions at the cell centre, respectively. The time lag is nondimensionalised by the local Kolmogorov time scales, given in Table 1 calculated from direct numerical simulations using the same parameter settings, see Alards et al (2017) and Rajaei (2017) for the details of the numerical method. Note that the Kolmogorov time scale differs depending on the position within the cylinder.…”

Section: Lagrangian Velocity Autocorrelationmentioning

confidence: 99%

“…Rossby (1969); Boubnov & Golitsyn (1986); Zhong et al (1993); Liu & Ecke (1997); Sakai (1997); Vorobieff & Ecke (2002); Kunnen et al (2008); King et al (2009); Zhong & Ahlers (2010); Niemela et al (2010); Kunnen et al (2010); Weiss & Ahlers (2011 a ); Kunnen et al (2014); Ecke & Niemela (2014); Rajaei et al (2017), numerical simulations, e.g. Julien et al (1996); Kunnen et al (2006); King et al (2009); Schmitz & Tilgner (2009); Stevens et al (2010); Julien et al (2012 b ); Stellmach et al (2014); Horn & Shishkina (2015); Alards et al (2017) and theoretical analysis, e.g. Chandrasekhar (1961); Chan (1974); Constantin et al (1999); Doering & Constantin (2001); Vitanov (2003); King et al (2012).…”

Section: Introductionmentioning

confidence: 99%

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Velocity and acceleration statistics in rapidly rotating Rayleigh–Bénard convection

et al. 2018

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Background rotation causes different flow structures and heat transfer efficiencies in Rayleigh–Bénard convection (RBC). Three main regimes are known: rotation-unaffected, rotation-affected and rotation-dominated. It has been shown that the transition between rotation-unaffected and rotation-affected regimes is driven by the boundary layers. However, the physics behind the transition between rotation-affected and rotation-dominated regimes are still unresolved. In this study, we employ the experimentally obtained Lagrangian velocity and acceleration statistics of neutrally buoyant immersed particles to study the rotation-affected and rotation-dominated regimes and the transition between them. We have found that the transition to the rotation-dominated regime coincides with three phenomena; suppressed vertical motions, strong penetration of vortical plumes deep into the bulk and reduced interaction of vortical plumes with their surroundings. The first two phenomena are used as confirmations for the available hypotheses on the transition to the rotation-dominated regime while the last phenomenon is a new argument to describe the regime transition. These findings allow us to better understand the rotation-dominated regime and the transition to this regime.

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Section: Lagrangian Velocity Autocorrelationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Velocity and acceleration statistics in rapidly rotating Rayleigh–Bénard convection

et al. 2018

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“…Numerical studies were primarily focused on the turbulent dispersion of Lagrangian particle pairs [5] and tetrads [6], the entropy production rates along individual Lagrangian trajectories [7] for convection volumes with aspect ratios Γ = L/H ≤ 4 where L is a horizontal extension (side length or diameter). Characteristic turnover times and the geometry of Lagrangian trajectories were analyzed numerically in closed non-rotating [8] and in rotating cells [9,10]. Laboratory experiments of turbulent convection pioneered the use of smart particles to measure local heat fluxes [11] along individual particle tracks.…”

Section: Introductionmentioning

confidence: 99%

Probing turbulent superstructures in Rayleigh-Bénard convection by Lagrangian trajectory clusters

et al. 2018

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We analyze large-scale patterns in three-dimensional turbulent convection in a horizontally extended square convection cell by Lagrangian particle trajectories calculated in direct numerical simulations. A simulation run at a Prandtl number Pr = 0.7, a Rayleigh number Ra = 10 5 , and an aspect ratio Γ = 16 is therefore considered. These large-scale structures, which are denoted as turbulent superstructures of convection, are detected by the spectrum of the graph Laplacian matrix. Our investigation, which follows Hadjighasem et al., Phys. Rev. E 93, 063107 (2016), builds a weighted and undirected graph from the trajectory points of Lagrangian particles. Weights at the edges of the graph are determined by a mean dynamical distance between different particle trajectories. It is demonstrated that the resulting trajectory clusters, which are obtained by a subsequent k-means clustering, coincide with the superstructures in the Eulerian frame of reference. Furthermore, the characteristic times τ L and lengths λ L U of the superstructures in the Lagrangian frame of reference agree very well with their Eulerian counterparts, τ and λU , respectively. This trajectory-based clustering is found to work for times t τ ≈ τ L . Longer time periods t τ L require a change of the analysis method to a density-based trajectory clustering by means of timeaveraged Lagrangian pseudo-trajectories, which is applied in this context for the first time. A small coherent subset of the pseudo-trajectories is obtained in this way consisting of those Lagrangian particles that are trapped for long times in the core of the superstructure circulation rolls and are thus not subject to ongoing turbulent dispersion.

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“…Instantaneous measures for this geometry are the curvature and torsion of trajectories. Such curvature and torsion measurements of tracer trajectories in rotating RBC have shown that the predictions for the scaling of curvature and torsion probability density functions (PDFs) derived for homogeneous isotropic turbulence (HIT) [12][13][14][15] are recovered, as long as measurements are performed in the turbulent bulk [16]. In the BLs, the PDFs scale differently consistent with the type of BL, which is the Prandtl-Blasius type in the regime dominated by the LSC and the Ekman type in the regime affected by vertically aligned vortices.…”

Section: Introductionmentioning

confidence: 99%

“…In RBC, trajectories are additionally expected to be affected by the large-scale coherent flow structures at larger timescales. We therefore extend the previous study on instantaneous measurements of the geometry of tracer trajectories [16] to scale-dependent measurements of this geometry by computing the directional change of tracer trajectories in (rotating) RBC up to the timescale of the large-scale coherent flow structures.…”

Section: Introductionmentioning

confidence: 99%

Directional change of tracer trajectories in rotating Rayleigh-Bénard convection

et al. 2018

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The angle of directional change of tracer trajectories in rotating Rayleigh-Bénard convection is studied as a function of the time increment τ between two instants of time along the trajectories, both experimentally and with direct numerical simulations. Our aim is to explore the geometrical characterization of flow structures in turbulent convection in a wide range of timescales and how it is affected by background rotation. We find that probability density functions (PDFs) of the angle of directional change θ(t,τ) show similar behavior as found in homogeneous isotropic turbulence, up to the timescale of the large-scale coherent flow structures. The scaling of the averaged (over particles and time) angle of directional change Θ(τ)=〈|θ(t,τ)|〉 with τ shows a transition from the ballistic regime [Θ(τ)∼τ^{c} with c=1] for τ≲τ_{η}, with τ_{η} the Kolmogorov timescale, to a scaling with smaller exponent c for τ_{η}≲τ≲T_{L}, with T_{L} the Lagrangian integral timescale. This scaling exponent is approximately constant in the weakly rotating regime (Rossby number Ro≳2.5) and is decreasing for increasing rotation rates when Ro≲2.5. We show that this trend in the scaling exponent is related with the large-scale coherent structures in the flow; the large-scale circulation for Ro≳2.5 and vertically aligned vortices emerging from the boundary layers (BLs) near the top and bottom plates and penetrating into the bulk for Ro≲2.5. In the viscous BLs, the PDFs of θ(t,τ) and scaling properties of Θ(τ) are in general different from those measured in the bulk and depend on the type of boundary layer, in particular whether the BL is of Prandtl-Blasius type (Ro≳2.5) or of Ekman type (Ro≲2.5). When it is of Ekman type, a stronger dynamic coupling exists between the BL and the bulk of the flow, resulting in similar scaling exponents in BL and bulk.

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Geometry of tracer trajectories in rotating turbulent flows

Cited by 9 publications

References 39 publications

Velocity and acceleration statistics in rapidly rotating Rayleigh–Bénard convection

Velocity and acceleration statistics in rapidly rotating Rayleigh–Bénard convection

Probing turbulent superstructures in Rayleigh-Bénard convection by Lagrangian trajectory clusters

Directional change of tracer trajectories in rotating Rayleigh-Bénard convection

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