Ion phase-space vortices in 2.5-dimensional simulations

Børve, S.; Pécseli, H. L.; Trulsen, J.

doi:10.1017/s0022377801008947

Cited by 20 publications

(35 citation statements)

References 12 publications

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“…The conspicuous features of the potential structures seem to be associated with phase space vortices, where all the relevant dynamics seem to take place in {x, v x }-plane, as expected for potential structures elongated in the y-direction, as here. Such ion phase space vortices are well-known, and have been observed experimentally by Pécseli et al (1981Pécseli et al ( , 1984, as well as in a number of numerical simulations (Sakanaka, 1972;Børve et al, 2001;Daldorff et al, 2001;. In particular, the coalescence seen in Fig.…”

Section: Numerical Resultssupporting

confidence: 60%

“…There are not the same particles which constitute a structure at all times. Studies of the lifetime of ion phase space vortices (Pécseli et al, 1984;Børve et al, 2001) refer to initial value problems, and do not apply for the present case. If ion phase space vortices were to be analyzed as initial value problems with these plasma parameters, the resulting structures would appear as transient phenomena.…”

Section: Kinetic Instabilitymentioning

confidence: 99%

See 1 more Smart Citation

Phase space structures generated by absorbing obstacles in streaming plasmas

Guio

Pécseli

2005

Ann. Geophys.

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Abstract. The dynamic behavior of a collisionless plasma flowing around an obstacle is investigated by numerical methods. In the present studies, the obstacle is formed by an absorbing cylinder, and a 2-D electrostatic particle-in-cell simulation is used to study the flow characteristics, with extensions to a fully 3-D generalization of the problem demonstrated as well. The formation of irregular filamented density depletions, oblique to the flow, is observed. The structures form behind the obstacle, in a region with a strong velocity shear, but also other instability mechanisms can be identified. The dynamics of these structures is highly dependent on the physical parameters of the plasma, and they can either be quasi-stationary or undergo a dynamic evolution. The structures are found to be associated with phase-space vortices, observed especially in the phase space spanned by the velocity direction perpendicular to the flow and the spatial coordinate in the same direction. The bias of the obstacle with respect to the plasma potential is found to be an important parameter for the dynamics of the structures, but seemingly not for their formation as such. The results can be of interest in the interpretation of structures in space plasmas as observed by instrumented spacecrafts.

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Section: Numerical Resultssupporting

confidence: 60%

Section: Kinetic Instabilitymentioning

confidence: 99%

Phase space structures generated by absorbing obstacles in streaming plasmas

Guio

Pécseli

2005

Ann. Geophys.

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“…2.2, with the only complication here being a nonlinear Poisson equation Børve et al, 2001). This equation is solved by a nonlinear multigrid method, which consists of a full multigrid schedule with an adaptive strategy that allows one to skip the coarse-grid correction if the specified accuracy is already reached on that grid.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…For very high ion beam velocities, the plasma will remain unstable, but in this case, for waves on the ion cyclotron branch . In this case, the linearly most unstable waves propagate with at an angle to the magnetic field (Michelsen, 1976), and no phase space vortices are formed (see also summary by Børve et al, 2001). The plasma is stable for small ion beam velocities below the sound speed, and it turns out that ion holes are being formed in a rather narrow "window" of ion beam velocities, and the variation of hole widths for varying ion beam velocities is rather modest .…”

Section: Numerical Resultsmentioning

confidence: 99%

Phase space vortices in collisionless plasmas

Guio

Børve

Daldorff

et al. 2003

Nonlin. Processes Geophys.

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Abstract.Results on the formation and propagation of electron phase space vortices from laboratory experiments are summarized. The electron phase space vortices were excited in a strongly magnetized Q-machine plasma by applying a pulse to a segment of a waveguide surrounding the plasma. Depending on the temporal variation of the applied pulse, one or more phase space vortices can be excited, and their interaction can be followed in space and time. We were able to demonstrate, for instance, an irreversible coalescence of two such vortices. These results are extended by numerical simulations, showing how electron phase space vortices can also be formed by beam instabilities. Furthermore, a study of ion phase space vortices is performed by numerical simulations. Both codes allow for an externally applied magnetic field in three spatial dimensions. Ion phase space vortices are formed by the nonlinear saturation of the ion-ion two-stream instability, excited by injecting an ion beam at the plasma boundary. By following the evolution of the ion distribution of the velocity perpendicular to the direction of propagation of the injected ion beam, we find a significant ion heating in the direction perpendicular to the magnetic field associated with the ion phase space vortices being formed. The results are relevant, for instance, for the interpretation of observations by instrumented spacecraft in the Earth's ionosphere and magnetosphere.

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“…To investigate non-linear effects and to overcome diagnostic difficulties, simulations have been a useful tool [e.g. [17][18][19][20][21] to the point where comparisons with naturally observed structures can be made with remarkable accuracy [22,23].…”

Section: Introductionmentioning

confidence: 99%

The effect of boundaries on the ion acoustic beam-plasma instability in experiment and simulation

et al. 2014

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The ion acoustic beam-plasma instability is known to excite strong solitary waves near the Earth's bowshock. Using a Double Plasma experiment, tightly coupled with a 1-dimensional Particle-in-Cell simulation, the results presented here show that this instability is critically sensitive to the experimental conditions. Boundary effects, which do not have any counterpart in space or in most simulations, unavoidably excite parasitic instabilities. Potential fluctuations from these instabilities lead to an increase of the beam temperature which reduces the growth rate such that non-linear effects leading to solitary waves are less likely to be observed. Furthermore, the increased temperature modifies the range of beam velocities for which an ion acoustic beam plasma instability is observed.

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Ion phase-space vortices in 2.5-dimensional simulations

Cited by 20 publications

References 12 publications

Phase space structures generated by absorbing obstacles in streaming plasmas

Phase space structures generated by absorbing obstacles in streaming plasmas

Phase space vortices in collisionless plasmas

The effect of boundaries on the ion acoustic beam-plasma instability in experiment and simulation

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