Geodesic
Positive Solutions of the Falkner–Skan Equation Arising in the Boundary Layer Theory
Canadian mathematical bulletin, Tome 51 (2008) no. 3, pp. 386-398

Voir la notice de l'article provenant de la source Cambridge University Press

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 $\text{ }\!\!\lambda\!\!\text{}\!\!\pi\!\!\text{ /2}$ , where $\text{ }\!\!\lambda\!\!\text{ }\,\in \,\mathbb{R}$ is a parameter involved in the equation. It is known that there exists ${{\text{ }\!\!\lambda\!\!\text{ }}^{*}}\,<\,0$ such that the equation with suitable boundary conditions has at least one positive solution for each $\text{ }\!\!\lambda\!\!\text{ }\,\ge \,{{\text{ }\!\!\lambda\!\!\text{ }}^{*}}$ and has no positive solutions for $\text{ }\!\!\lambda\!\!\text{ }\,<\,{{\text{ }\!\!\lambda\!\!\text{ }}^{*}}$ . The known numerical result shows ${{\text{ }\!\!\lambda\!\!\text{ }}^{*}}\,=\,-0.1988$ . In this paper, ${{\text{ }\!\!\lambda\!\!\text{ }}^{*}}\,\in \,[-0.4,\,-0.12]$ 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.
DOI : 10.4153/CMB-2008-039-7
Mots-clés : 34B16, 34B18, 34B40, 76D10, Falkner–Skan equation, boundary layer problems, singular integral equation, positive solutions 
Lan, K. Q.; Yang, G. C. Positive Solutions of the Falkner–Skan Equation Arising in the Boundary Layer Theory. Canadian mathematical bulletin, Tome 51 (2008) no. 3, pp. 386-398. doi: 10.4153/CMB-2008-039-7
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