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Free surface flow due to a submerged source

In this thesis we consider the free surface flow due to a submerged source in a channel of finite depth. This problem has been considered previously in the literature, with some disagreement about whether or not a train of waves exist on the free surface for Froude numbers less than unity. The physical assumptions behind the accepted model are clearly stated and governing equations and boundary conditions derived. Complex variable theory is then employed to obtain a singular nonlinear integral equation, which describes the flow field completely. The integral equation is evaluated numerically using a collocation method, and implemented with mathematical software {\em Matlab}. The numerical solutions suggest that indeed waves do exist on the free surface, but are exponentially small in the limit that the Froude number approaches zero. An asymptotic expression is also derived to solve the integral equation, valid for small Froude numbers. This expansion is calculated to second order, which improves on the leading order solution given previously in the literature. Such a scheme is unable to predict waves on the free surface, since they are exponentially small. It is discussed how exponential asymptotics could be used to derive a more accurate analytic solution that describes waves on the free surface.