Self-organization and transition to turbulence in isotropic fluid motion driven by negative damping at low wavenumbers

A. Berera; B. Jankauskas; M. F. Linkmann; S. R. Yoffe; W. D. McComb

arxiv: 1410.2987 · v4 · pith:B3HXY3X5new · submitted 2014-10-11 · ⚛️ physics.flu-dyn · nlin.AO

Self-organization and transition to turbulence in isotropic fluid motion driven by negative damping at low wavenumbers

W. D. McComb , M. F. Linkmann , A. Berera , S. R. Yoffe , B. Jankauskas This is my paper

classification ⚛️ physics.flu-dyn nlin.AO

keywords self-organizedstatetransitionalignedbecomingbeltramicontaineddamping

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We observe a symmetry-breaking transition from a turbulent to a self-organized state in direct numerical simulation of the Navier-Stokes equation at very low Reynolds number. In this self-organized state the kinetic energy is contained only in modes at the lowest resolved wavenumber, the skewness vanishes, and visualization of the flows shows a lack of small-scale structure, with the vorticity and velocity vectors becoming aligned (a Beltrami flow).

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Self-organization and transition to turbulence in isotropic fluid motion driven by negative damping at low wavenumbers

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