European Turbulence Conference 14

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New conservation laws for helically symmetric flows and their importance for tubulence theory

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Our present understanding of statistical 3D turbulence dynamics for reasonable large wave numbers (or small scales) largely
relies on the dissipation of kinetic energy a quantity which is invariant under all symmetry groups of Navier-Stokes equations except
some special combination of the scaling groups. On the other hand in 2D turbulence, which is translational invariant in one direction,
the transfer mechanism among scales is rather different since the vortex stretching is non-existing. Instead, the transfer and scale
determining key invariant is enstrophy: an area integral of the vorticity squared which is one of the infinite many integral invariants
of 2D inviscid fluid mechanics (see 4 below). Hence the basic mechanism between and 2D and 3D turbulence is very different. To
close this gap we consider flows with a helical symmetry which is a twist of translational and rotational symmetry. The resulting equa-
tions are "2 1 D" which means they have three independent velocity components though only two independent spatial variables. We 2
presently show that the helically symmetric equations of motion admit an infinite number of new non-trivial conservation laws (CL). It is to be expected that the new CLs may give some deeper insight into turbulence dynamics and hence bridging 2D and 3D turbulence.

Author(s):

Olga Kelbin    
Chair of Fluid Dynamics, Department of Mechanical Engineering, Technische Universität Darmstadt
Germany

Alexei Cheviakov    
Department of Mathematics and Statistics, University of Saskatchewan
Canada

Martin Oberlack    
Chair of Fluid Dynamics, Department of Mechanical Engineering, Technische Universität Darmstadt
Germany

Ivan Delbende    
Université Pierre et Marie Curie-Paris 6, LIMSI-CNRS
France

 

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