Buoyancy-Driven Flow through a Bed of Solid Particles Produces a New Form of Rayleigh-Taylor Turbulence
Journal article, 2018
Rayleigh-Taylor (RT) fluid turbulence through a bed of rigid, finite-size spheres is investigated by means of high-resolution direct numerical simulations, fully coupling the fluid and the solid phase via a state-of-the-art immersed boundary method. The porous character of the medium reveals a totally different physics for the mixing process when compared to the well-known phenomenology of classical RT mixing. For sufficiently small porosity, the growth rate of the mixing layer is linear in time (instead of quadratical) and the velocity fluctuations tend to saturate to a constant value (instead of linearly growing). We propose an effective continuum model to fully explain these results where porosity originated by the finite-size spheres is parametrized by a friction coefficient.
Author
[Person e035f886-7ab8-4df7-8adf-74df7012270e not found]
[Person 975c6c76-a064-4569-93c2-3e99d754a497 not found]
[Person 037a5c5d-e681-493d-a6b9-9613a635a402 not found]
[Person 1ca42ee8-cfb9-4d2a-9287-0115a2c59a78 not found]
Physical Review Letters
0031-9007 (ISSN) 1079-7114 (eISSN)
Vol. 121 22 224501Driving Forces
Sustainable development
Subject Categories (SSIF 2011)
Applied Mechanics
Computational Mathematics
Fluid Mechanics and Acoustics
Areas of Advance
Production
Energy
Roots
Basic sciences
DOI
10.1103/PhysRevLett.121.224501