J. Thomas Beale scite author profile

The authors prove that the maximum norm of the vorticity controls the breakdown of smooth solutions of the 3-D Euler equations. In other words, if a solution of the Euler equations is initally smooth and loses its regularity at some later time, then the maximum vorticity necessarily grows without bound as the critical time approaches equivalently, if the vorticity remains bounded, a smooth solution persists.

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The initial value problem for the navier‐stokes equations with a free surface

Beale

1981

Comm Pure Appl Math

227

333

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Large-time regularity of viscous surface waves

Beale

1984

Arch. Rational Mech. Anal.

240

187

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Growth rates for the linearized motion of fluid interfaces away from equilibrium

Beale

Hou

Lowengrub

1993

Comm Pure Appl Math

147

188

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We consider the motion of a two-dimensional interface separating an inviscid, incompressible, irrotational fluid, influenced by gravity, from a region of zero density. We show that under certain conditions the equations of motion, linearized about a presumed time-dependent solution, are wellposed that is, linear disturbances have a bounded rate of growth. If surface tension is neglected, the linear equations are well-posed provided the underlying exact motion satisfies a condition on the acceleration of the interface relative to gravity, similar to the criterion formulated by G. I. Taylor. If surface tension is included, the linear equations are well-posed without qualifications, whether the fluid is above or below the interface. An interesting qualitative structure is found for the linear equations. A Lagrangian approach is used, like that of numerical work such as [3], except that the interface is assumed horizontal at infinity. Certain integral equations which occur, involving double layer potentials, are shown to be solvable in the present case.

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Convergence of a Boundary Integral Method for Water Waves

Beale¹,

Hou²,

Lowengrub³

1996

SIAM J. Numer. Anal.

154

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Abstract. We prove nonlinear stability and convergence of certain boundary integral methods for time-dependent water waves in a two-dimensional, inviscid, irrotational, incompressible fluid, with or without surface tension. The methods are convergent as long as the underlying solution remains fairly regular (and a sign condition holds in the case without surface tension). Thus, numerical instabilities are ruled out even in a fully nonlinear regime. The analysis is based on delicate energy estimates, following a framework previously developed in the continuous case [Beale, Hou, and Lowengrub, Comm. Pure Appl. Math., 46 (1993), pp. 1269-1301. No analyticity assumption is made for the physical solution. Our study indicates that the numerical methods must satisfy certain compatibility conditions in order to be stable. Violation of these conditions will lead to numerical instabilities. A breaking wave is calculated as an illustration.

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J. Thomas Beale

Remarks on the breakdown of smooth solutions for the 3-D Euler equations

The initial value problem for the navier‐stokes equations with a free surface

Large-time regularity of viscous surface waves

Growth rates for the linearized motion of fluid interfaces away from equilibrium

Convergence of a Boundary Integral Method for Water Waves

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