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arxiv: 1803.06079 · v1 · pith:3KNWGEHG · submitted 2018-03-16 · physics.plasm-ph

Electron hole instability in linearly sub-critical plasmas

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classification physics.plasm-ph
keywords electronenergynon-linearplasmaacousticdrivenholeholes
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Electron holes (EH) are highly stable non-linear structures met omnipresently in driven collision-less hot plasmas. A mechanism destabilizing small perturbations into holes is essential for an often witnessed but less understood sub-critically driven intermittent plasma turbulence. In this paper we show how a tiny, eddy-like, non-topological seed fluctuation can trigger an unstable evolution deep in the linearly damped region, a process being controlled by the trapping non-linearity and hence being beyond the realm of the Landau scenario. After a (transient) transition phase modes of the privileged spectrum of cnoidal EH are excited which in the present case consist of a solitary electron hole (SEH), two counter-propagating "Langmuir" modes (plasma oscillation), and an ion acoustic mode. A quantitative explanation involves employing non-linear eigen-modes, yielding a non-linear dispersion relation with a forbidden regime and the negative energy character of the SEH, properties being inherent in Schamel's model of undamped Vlasov-Poisson structures identified here as lowest order trapped particle equilibria. An important role in the final adaption of nonlinear plasma eigenmodes is played by a deterministic response of trapped electrons which facilitates transfer of energy from electron thermal energy to an ion acoustic non-uniformity, accelerating the SEH and positioning it into the right place assigned by the theory.

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