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Explore advanced mathematical analysis of fluid boundary layers in this lecture focusing on instabilities and singularities within the Prandtl boundary layer model. Examine the mathematical foundations of incompressible fluid behavior with small viscosity near solid walls, building on classical methods from Oleinik's work in the 1960s while incorporating recent developments in the field. Investigate the well-posedness of 2D equations in stationary cases without reversed flow, then delve into the complex phenomena occurring near separation points and within recirculation zones where singularities typically emerge. Analyze how these mathematical singularities challenge the validity of traditional models and explore potential alternative approaches for describing fluid behavior in these critical regions. Study time-dependent cases where the system maintains well-posedness in Sobolev spaces under monotone tangential velocity conditions, and understand why this assumption represents an essentially optimal requirement. Discover how instabilities develop near non-monotone shear flows and learn why these prevent well-posedness in Sobolev spaces. Examine related mathematical frameworks including interactive boundary layer systems and triple deck systems as variants of the classical Prandtl approach. Gain insight into current open problems in the field, including the search for replacement models near separation points and modifications needed to avoid singularities in recirculation zones.
