Joseph Oloo
Collapses of linearly decaying three-dimensional perturbations in homogeneous and weakly stratified boundary layers
Oloo, Joseph
Authors
Abstract
The physical mechanisms of why an orderly laminar flow suddenly becomes turbulent are still poorly understood, despite more than a century of incessant efforts. The thesis puts forward a radically new approach to understanding the fundamental challenge of bypass laminar-turbulent transition. In contrast to the overwhelming
majority of other transition studies are concerned primarily with linear instabilities, here the focus is on finite amplitude three-dimensional (3d) longwave perturbations of the boundary layer which are weakly decaying in the linear approximation.
The principal novelty is in simultaneous account of viscous decay, three-dimensionality and nonlinearity. To describe analytically the dynamics of such perturbations Witham type pseudo-differential nonlinear evolution equations have been derived and examined. The equations are derived asymptotically in the distinguished limit: nonlinearity, dispersion and viscous decay (shown to be described by the Rayleigh friction type term) are assumed to be in balance. The two models describe the 3d perturbations in generic semi-infinite uniform boundary layers for unidirectional flows in homogeneous and weakly stratified fluids (the equation for the homogeneous case is the essentially two-dimensional Benjamin-Ono equation modified by the account of the Rayleigh friction term), while the third one examines the effect of confined boundary layer in homogeneous fluids.
The key feature of the derived models is that they support collapse, i.e. a specific blow up with formation of a point singularity in finite time. Self-similar solutions describing behaviour of the solution in the neighbourhood of singularity have been derived for all three models. The phase space of these models is simply organised: there are
two attractors corresponding to the unperturbed linearly stable boundary layer and the singularity. The boundary in the space of the initial conditions separating the regimes of collapse and decay has been examined analytically and numerically. For the situations where the Rayleigh friction is negligible, the systems are Hamiltonian
and an analytical criterion of vanishing of the Hamiltonian specifies the boundary between the regimes. For other situations, the boundary is found by direct numerical simulations of the evolution equations.
The overall conclusion is that neither the Rayleigh friction, nor stratification or effect of a second boundary prevent collapse from happening, nor they change the perturbation amplitude time dependence in the vicinity of the singularity, however, these factors do affect the evolution and can strongly increase the amplitude threshold of collapse, often beyond the range of validity of weakly nonlinear models. Thus, within the framework of the derived weakly nonlinear models a broad class of initial conditions tends to form a singularity, in the process of evolution the emerging patterns strongly resemble the 3d coherent structures observed in the wind tunnel boundary layers.
Citation
Oloo, J. Collapses of linearly decaying three-dimensional perturbations in homogeneous and weakly stratified boundary layers. (Thesis)
Thesis Type | Thesis |
---|---|
Deposit Date | Sep 22, 2023 |
Award Date | Dec 2, 2020 |
You might also like
Boundary layer collapses described by the two-dimensional intermediate long-wave equation
(2020)
Journal Article
: Collapses in the oceanic Ekman boundary layer
(2022)
Presentation / Conference Contribution
Blow-up of subsurface vorticity waves in the ocean under strong winds
(2019)
Presentation / Conference Contribution
Downloadable Citations
About Edinburgh Napier Research Repository
Administrator e-mail: repository@napier.ac.uk
This application uses the following open-source libraries:
SheetJS Community Edition
Apache License Version 2.0 (http://www.apache.org/licenses/)
PDF.js
Apache License Version 2.0 (http://www.apache.org/licenses/)
Font Awesome
SIL OFL 1.1 (http://scripts.sil.org/OFL)
MIT License (http://opensource.org/licenses/mit-license.html)
CC BY 3.0 ( http://creativecommons.org/licenses/by/3.0/)
Powered by Worktribe © 2024
Advanced Search