Tom Solomon scite author profile

The transport of passive impurities in nearly two-dimensional, time-periodic Rayleigh-Benard convection is studied experimentally and numerically. The transport may be described as a onedimensional diffusive process with a local effective diffusion constant D (x) that is found to depend linearly on the local amplitude of the roll oscillation. The transport is independent of the molecular diffusion coefficient and is enhanced by 1-3 orders of magnitude over that for steady convective flows. The local amplitude of oscillation shows strong spatial variations, causing D*(x) to be highly nonuniform. Computer simulations of a simplified model show that the basic mechanism of transport is chaotic advection in the vicinity of oscillating roll boundaries. Numerical estimates of D are found to agree semiquantitatively with the experimental results. Chaotic advection is shown to provide a well-defined transition from the slow, diffusion-limited transport of time-independent cellular flows to the rapid transport of turbulent flows.

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Uniform resonant chaotic mixing in fluid flows

Solomon

Mezić

2003

Nature

123

106

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Laminar flows can produce particle trajectories that are chaotic, with nearby tracers separating exponentially in time. For time-periodic, two-dimensional flows and steady three-dimensional (3D) flows, enhancements in mixing due to chaotic advection are typically limited by impenetrable transport barriers that form at the boundaries between ordered and chaotic mixing regions. However, for time-dependent 3D flows, it has been proposed theoretically that completely uniform mixing is possible through a resonant mechanism called singularity-induced diffusion; this is thought to be the case even if the time-dependent and 3D perturbations are infinitesimally small. It is important to establish the conditions for which uniform mixing is possible and whether or not those conditions are met in flows that typically occur in nature. Here we report experimental and numerical studies of mixing in a laminar vortex flow that is weakly 3D and weakly time-periodic. The system is an oscillating horizontal vortex chain (produced by a magnetohydrodynamic technique) with a weak vertical secondary flow that is forced spontaneously by Ekman pumping--a mechanism common in vortical flows with rigid boundaries, occurring in many geophysical, industrial and biophysical flows. We observe completely uniform mixing, as predicted by singularity-induced diffusion, but only for oscillation periods close to typical circulation times.

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Chaotic advection in a two-dimensional flow: Lévy flights and anomalous diffusion

Solomon

Weeks

Swinney

1994

Physica D: Nonlinear Phenomena

146

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Long-term particle tracking is used to study chaotic transport experimentally in laminar, chaotic, and turbulent flows in an annular tank that rotates sufficiently rapidly to insure two-dimensionality of the flow. For the laminar and chaotic velocity fields, the flow consists of a chain of vortices sandwiched between unbounded jets. In these flow regimes, tracer particles stick for long times to remnants of invariant surfaces around the vortices, then make long excursions ("flights") in the jet regions. The probability distributions for the flight time durations exhibit power-law rather than exponential decays, indicating that the particle trajectories are described mathematically as L6vy flights (i.e. the trajectories have infinite mean square displacement per flight). Sticking time probability distributions are also characterized by power laws, as found in previous numerical studies. The mixing of an ensemble of tracer particles is superdiffusive: the variance of the displacement grows with time as t * with 1 < 3' < 2. The dependence of the diffusion exponent 3' and the scaling of the probability distributions are investigated for periodic and chaotic flow regimes, and the results are found to be consistent with theoretical predictions relating L6vy flights and anomalous diffusion. For a turbulent flow, the L6vy flight description no longer applies, and mixing no longer appears superdiffusive.

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Tom Solomon

Observation of anomalous diffusion and Lévy flights in a two-dimensional rotating flow

Chaotic particle transport in time-dependent Rayleigh-Bénard convection

Uniform resonant chaotic mixing in fluid flows

Chaotic advection in a two-dimensional flow: Lévy flights and anomalous diffusion

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