2011
DOI: 10.1140/epjp/i2011-11038-4
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Turbulence and coherent structures in non-neutral plasmas

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Cited by 15 publications
(26 citation statements)
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“…Although this situation is oversimplified and does not reproduce the most typical experimental conditions (discussed in the next Section), it already highlights the clear influence of dust contamination on the dynamics of the electron plasma. The results show that for the pure electron plasma the diocotron (Kelvin-Helmholtz) instability is fully developed over the span of the simulation and we can see the formation of five vortices (as seen both in the theory and experiments [8,7]). When dust is added we can clearly observe the presence of a higher number of active diocotron modes, with the formation of six vortices, but at the same time we can notice a slower overall dynamics (vortices are not fully developed yet), which means that the insurgence of the Kelvin-Helmholtz instability is effectively slowed down by the presence of the dust core.…”
Section: Numerical Investigationsmentioning
confidence: 63%
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“…Although this situation is oversimplified and does not reproduce the most typical experimental conditions (discussed in the next Section), it already highlights the clear influence of dust contamination on the dynamics of the electron plasma. The results show that for the pure electron plasma the diocotron (Kelvin-Helmholtz) instability is fully developed over the span of the simulation and we can see the formation of five vortices (as seen both in the theory and experiments [8,7]). When dust is added we can clearly observe the presence of a higher number of active diocotron modes, with the formation of six vortices, but at the same time we can notice a slower overall dynamics (vortices are not fully developed yet), which means that the insurgence of the Kelvin-Helmholtz instability is effectively slowed down by the presence of the dust core.…”
Section: Numerical Investigationsmentioning
confidence: 63%
“…Specifically, the aim is the observation of the modifications in the plasma dynamics due to the presence of a dust population, with a focus on the effects of dust on stability, fluid turbulence and equilibrium properties of the electron component. The study comprises both a theoretical/numerical analysis and the design and realization of a Penning-Malmberg trap for tailored experiments, and represents a continuation and extension of the studies on pure electron plasmas previously performed within our research group [8].…”
Section: Introductionmentioning
confidence: 99%
“…The equations form a noncanonical Hamiltonian system [19], characterized by the existence of two independent families of Casimir invariants, given by C 1 = dAF (n e ) and C 2 = dAd 2 vG ( f d ), with F and G arbitrary functions. The invariants include, as particular cases, the familiar invariants of the 2D Euler incompressible equations [20,9], such as the enstrophy, and those of the Vlasov equation, such as the entropy. In particular, the Hamiltonian structure of the model can be used to derive a set of stability conditions for rotating coherent structures of the two-species system.…”
Section: Physical Modelmentioning
confidence: 99%
“…The project shows aspects of significant novelty in the field of complex plasmas, with a combination of plasma magnetization, nonneutrality and dust contamination. A particular goal is the analysis of the effects of dust on the instabilities and the evolution of the turbulence of the electron component [9]. The analysis is restricted so far to the transverse dynamics of the system.…”
Section: Introductionmentioning
confidence: 99%
“…A further simplification that can be adopted for these systems consists of considering a 2D dynamics. For pure electron plasmas in Penning-Malmberg traps the high-frequency longitudinal electron motion can be averaged out for a wide range of operational regimes, and the electron plasma dynamics becomes isomorphic to that of a 2D incompressible inviscid fluid, where the fluid vorticity corresponds to the electron density and the fluid stream function to the electrostatic potential [6,7]. A 2D multi-fluid model turns out to be appropriate also for a cold non-relativistic electronion system at high magnetic field strengths [1], while a kinetic treatment for the dynamics of the ion population is required at moderate values of the confining field.…”
mentioning
confidence: 99%