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Positive Solutions of the Falkner--Skan Equation Arising in the Boundary Layer Theory |
Published:2008-09-01
Printed: Sep 2008
Printed: Sep 2008
- K. Q. Lan
- G. C. Yang
Abstract
The well-known Falkner--Skan equation is one of the most important
equations in laminar boundary layer theory and is used to describe
the steady two-dimensional flow of a slightly viscous
incompressible fluid past wedge shaped bodies of angles related to
$\lambda\pi/2$, where $\lambda\in \mathbb R$ is a parameter
involved in the equation. It is known that there exists
$\lambda^{*}<0$ such that the equation with suitable boundary
conditions has at least one positive solution for each $\lambda\ge
\lambda^{*}$ and has no positive solutions for
$\lambda<\lambda^{*}$. The known numerical result shows
$\lambda^{*}=-0.1988$. In this paper, $\lambda^{*}\in
[-0.4,-0.12]$ is proved analytically by establishing a singular
integral equation which is equivalent to the Falkner--Skan
equation. The equivalence result
provides new techniques to study properties and existence of solutions of
the Falkner--Skan equation.
| Keywords: | Falkner-Skan equation, boundary layer problems, singular integral equation, positive solutions |
| MSC Classifications: |
34B16 - Singular nonlinear boundary value problems 34B18 - Positive solutions of nonlinear boundary value problems 34B40 - Boundary value problems on infinite intervals 76D10 - Boundary-layer theory, separation and reattachment, higher-order effects |