Lagrangian transport in a class of three-dimensional buoyancy-driven flows

The present study concerns the Lagrangian dynamics of three-dimensional (3D) buoyancy-driven cavity flows under steady and laminar conditions due to a global temperature gradient imposed via an opposite hot and cold sidewall. This serves as the archetypal configuration for natural-convection flows i...

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Bibliographic Details
Published inJournal of fluid mechanics Vol. 832; pp. 5 - 40
Main Authors Contreras, P. S., Speetjens, M. F. M., Clercx, H. J. H.
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 10.12.2017
Subjects
Bifurcations
Broken symmetry
Buoyancy
Computer applications
Convection
Dynamic structural analysis
Dynamics
Fluid inertia
Fluid mechanics
Global temperatures
Grashof number
Gravitation
Gravity
Inertia
Interactions
Kinematics
Laboratories
Laminar flow
Properties
Spacetime
Stagnation
Streamlines
Studies
Temperature gradients
Three dimensional flow
Topology
Toruses
Transport
Transport properties
chaotic advection
convection in cavities
topological fluid dynamics
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Summary:The present study concerns the Lagrangian dynamics of three-dimensional (3D) buoyancy-driven cavity flows under steady and laminar conditions due to a global temperature gradient imposed via an opposite hot and cold sidewall. This serves as the archetypal configuration for natural-convection flows in which (contrary to the well-known Rayleigh–Bénard flow) gravity is perpendicular (instead of parallel) to the global temperature gradient. Limited insight into the Lagrangian properties of this class of flows, despite its relevance to observed flow phenomena as well as scalar transport, motivates this study. The 3D Lagrangian dynamics are investigated in terms of the generic structure and associated transport properties of the global streamline pattern (‘Lagrangian flow topology’) by both theoretical and computational analyses. The Grashof number $Gr$ is the principal control parameter for the flow topology: limit $Gr=0$ yields a trivial state of closed streamlines; $Gr>0$ induces symmetry breaking by fluid inertia and buoyancy and thus causes formation of toroidal coherent structures (‘primary tori’) embedded in chaotic streamlines governed by Hamiltonian mechanisms. Fluid inertia prevails for ‘smaller’ $Gr$ and gives behaviour that is dynamically entirely analogous to 3D lid-driven cavity flows. Buoyancy-induced bifurcation of the flow topology occurs for ‘larger’ $Gr$ and underlies the emergence of ‘secondary rolls’ observed in the literature and to date unreported secondary tori for ‘larger’ Prandtl numbers $Pr$ . Key to these dynamics are stagnation points and corresponding heteroclinic manifold interactions.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2017.680