Susan Friedlander scite author profile

Onsager conjectured that weak solutions of the Euler equations for incompressible fluids in R 3 conserve energy only if they have a certain minimal smoothness, (of order of 1/3 fractional derivatives) and that they dissipate energy if they are rougher. In this paper we prove that energy is conserved for velocities in the function space B 1/3 3,c(N) . We show that this space is sharp in a natural sense. We phrase the energy spectrum in terms of the Littlewood-Paley decomposition and show that the energy flux is controlled by local interactions. This locality is shown to hold also for the helicity flux; moreover, every weak solution of the Euler equations that belongs to B 2/3 3,c(N) conserves helicity. In contrast, in two dimensions, the strong locality of the enstrophy holds only in the ultraviolet range.

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Global well-posedness for an advection–diffusion equation arising in magneto-geostrophic dynamics

Friedlander

Vicol

2011

Ann. Inst. H. Poincaré C Anal. Non Linéaire

100

141

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We use De Giorgi techniques to prove Hölder continuity of weak solutions to a class of drift-diffusion equations, with L 2 initial data and divergence free drift velocity that lies in L ∞ t BM O −1 x . We apply this result to prove global regularity for a family of active scalar equations which includes the advection-diffusion equation that has been proposed by Moffatt in the context of magnetostrophic turbulence in the Earth's fluid core.2000 Mathematics Subject Classification. 76D03, 35Q35, 76W05.

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Nonlinear instability in an ideal fluid

Friedlander

Strauss

Vishik

1997

Ann. Inst. H. Poincaré C Anal. Non Linéaire

127

102

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Linearized instability implies nonlinear instability under certain rather general conditions. This abstract theorem is applied to the Euler equations governing the motion of an inviscid fluid. In particular this theorem applies to all 2D space periodic flows without stagnation points as well as 2D space-periodic shear flows. Résumé L’instabilité linéarisée implique l’instabilité non linéaire sous certaines conditions assez générales. Ce théorème abstrait s’applique aux équations d’Euler qui gouvernent le mouvement d’un fluide non visqueux. En particulier ce théorème s’applique à tous les flots périodiques dans le plan, soit sans point de stagnation, soit des écoulements de cisaillement.

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Instability criteria for the flow of an inviscid incompressible fluid

1991

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We present a geometric estimate from below on the growth rate of a small perturbation of a threedimensional steady flow of an ideal fluid and thus we obtain effective criteria for local instability for Euler's equations. We use these criteria to demonstrate the instability of several simple flows and to show that any flow with a hyperbolic stagnation point is unstable.PACS numbers: 47.20.-k In a companion paper Vishik and Friedlander 1 obtain a universal geometric estimate from below on the growth rate of a small perturbation of a three-dimensional steady flow of an inviscid incompressible fluid. In this Letter we discuss certain implications concerning instability for Euler's equations that follow from the existence of this estimate and we demonstrate that the estimate gives effective criteria for local instability. In particular, the existence of a hyperbolic stagnation point implies that the steady flow is unstable. An important feature of our approach which allows us to obtain effective criteria is that, unlike many previous approaches to hydrodynamic stability, we do not study the spectrum but rather we consider the growth rate of the relevant Green's function as t-> °°.There is a very extensive literature concerning the field of hydrodynamic stability (for references see, for example, Drazin and Reid 2 ). We briefly mention some of the work whose techniques are related to those that we employ. Eckhoff and Storesletten 3 and Eckhoff 4 study the stability of azimuthal shear flows of a compressible fluid and more generally symmetric hyperbolic systems using an approach based on the generalized progressing wave expansion. 5,6 Eckhoff shows that local instability problems for hyperbolic systems can be essentially reduced to a local analysis involving ordinary differential equations (ODE) and algebraic equations only. We show that the same conclusion can be drawn for Euler's equations for an ideal fluid. These equations do not form a hyperbolic system; hence several additional technical details arise in the analysis. Bayly 7 studies the stability of quasi-twodimensional steady flows via an analysis of a Floquet system of ODE. He shows that the Floquet exponent gives the growth rate for a family of instabilities which include the Rayleigh centrifugal instability, the LeibovichStewartson columnar instability, and the elliptic vortex instability. We note that the instability criteria that we present in this Letter are equivalent to those of Bayly in the particular case of quasi-two-dimensional steady flows. Lifschitz 8 uses WKB methods to construct part of the continuous spectrum for axisymmetric steady flows. Using methods inspired by magnetohydrodynamics, he obtains a necessary stability condition for a vortex ring with respect to localized three-dimensional perturbations.Let u(x) be a steady solution of Euler's equations governing the motion in 3D of an inviscid incompressible fluid:(1)The 3D vector field u(x) denotes the velocity and the scalar field P(x) denotes the pressure in the fluid. We consider the linear...

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On the ill/well-posedness and nonlinear instability of the magneto-geostrophic equations

Friedlander

Vicol

2011

Nonlinearity

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ABSTRACT. We consider an active scalar equation that is motivated by a model for magneto-geostrophic dynamics and the geodynamo. We prove that the non-diffusive equation is ill-posed in the sense of Hadamard in Sobolev spaces. In contrast, the critically diffusive equation is well-posed (cf. [15]). In this case we give an example of a steady state that is nonlinearly unstable, and hence produces a dynamo effect in the sense of an exponentially growing magnetic field.

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