Interplay between advective, diffusive and active barriers in (rotating) Rayleigh-Bénard flow
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https://hdl.handle.net/10037/32181Date
2023-08-22Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
Our understanding of the material organization of complex fluid flows has benefited
recently from mathematical developments in the theory of objective coherent structures.
These methods have provided a wealth of approaches that identify transport barriers
in three-dimensional (3-D) turbulent flows. Specifically, theoretical advances have been
incorporated into numerical algorithms that extract the most influential advective,
diffusive and active barriers to transport from data sets in a frame-indifferent fashion.
To date, however, there has been very limited investigation into these objectively defined
transport barriers in 3-D unsteady flows with complicated spatiotemporal dynamics.
Similarly, no systematic comparison of advective, diffusive and active barriers has
been carried out in a 3-D flow with both thermally driven and mechanically modified
structures. In our study, we utilize simulations of turbulent rotating Rayleigh–Bénard
convection to uncover the interplay between advective transport barriers (Lagrangian
coherent structures), material barriers to diffusive heat transport, and objective Eulerian
barriers to momentum transport. For a range of (inverse) Rossby numbers, we identify each
type of barrier and find intriguing relationships between momentum and heat transport
that can be related to changes in the relative influence of mechanical and thermal forces.
Further connections between bulk behaviours and structure-specific behaviours are also
developed.
Publisher
Cambridge University PressCitation
Aksamit, Hartmann, Lohse, Haller. Interplay between advective, diffusive and active barriers in (rotating) Rayleigh-Bénard flow. Journal of Fluid Mechanics. 2023;969Metadata
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