M. Parviainen scite author profile

M. Parviainen

5Publications

60Citation Statements Received

242Citation Statements Given

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145

227

Affiliations

Ruhr University Bochum, Linköping University

Publications

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Instability and dynamics of two nonlinearly coupled laser beams in a plasma

Shukła

Eliasson

Marklund

et al. 2006

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The nonlinear interaction between two laser beams in a plasma is investigated in the weakly nonlinear and relativistic regime. The evolution of the laser beams is governed by two nonlinear Schrödinger equations that are coupled with the slow plasma density response. A nonlinear dispersion relation is derived and used to study the growth rates of the Raman forward and backward scattering instabilities as well of the Brillouin and self-focusing/modulational instabilities. The nonlinear evolution of the instabilities is investigated by means of direct simulations of the time-dependent system of nonlinear equations.

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Electron surfing acceleration in oblique magnetic fields

Dieckmann

Eliasson

Parviainen

et al. 2006

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Initially, inhomogeneous plasma jets, ejected by active galactic nuclei and associated with gamma-ray bursts, are thermalized by the formation of internal shocks. Jet subpopulations can hereby collide at Lorentz factors of a few. As the resulting relativistic shock expands into the upstream plasma, a significant fraction of the upstream ions is reflected. These ions, together with downstream ions that leak through the shock, form relativistic beams of ions that outrun the shock. The thermalization of these beams via the two-stream instability is thought to contribute significantly to plasma heating and particle acceleration by the shock. Here, the capability of a two-stream instability to generate relativistic field-aligned and cross-field electron flow, is examined for a magnetized plasma by means of a particle-in-cell (PIC) simulation. The electrons interact with the developing quasi-electrostatic waves and oblique magnetic fields. The simulation results bring forward evidence that such waves, by their non-linear interactions with the plasma, produce a highly relativistic field-aligned electron flow and electron energies, which could contribute to the radio synchrotron emissions from astrophysical jets, to ultrarelativistic leptonic subpopulations propagating with the jet and to the halo particles surrounding the accretion disc of the black hole

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Numerical simulation and visualization of stochastic and ordered electron motion forced by electrostatic waves in a magnetized plasma

Dieckmann

Shukła

Parviainen

et al. 2005

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The interaction of electrons with strong electrostatic waves and an external magnetic field, which is oriented obliquely to the wave vector, leads to stochastic acceleration and acceleration by the cross-field transport of trapped electrons. This wave-particle interaction involves three velocity components of the electrons and, for a plane wave, one spatial position. The phase-space evolution is also affected by nonlinear oscillations in the amplitude of the saturated wave, and the system becomes explicitly time dependent. Here, the wave-particle interactions are investigated with a particle-in-cell simulation, and the results are visualized by examining orbits of individual electrons and also time-evolving phase-space structures. Two clearly distinct electron populations are identified, one due to cross-field transport and the other due to stochastic interactions, which are robust against growing secondary modes.

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Phase speed of electrostatic waves: the critical parameter for efficient electron surfing acceleration

Dieckmann

Sircombe

Parviainen

et al. 2006

Plasma Phys. Control. Fusion

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Particle acceleration by means of non-linear plasma wave interactions is of great topical interest. Accordingly, in this paper we focus on the electron surfing process. Self-consistent kinetic simulations, using both relativistic Vlasov and PIC (Particle In Cell) approaches, show here that electrons can be accelerated to highly relativistic energies (up to 100mec 2 ) if the phase speed of the electrostatic wave is mildly relativistic (0.6c to 0.9c for the magnetic field strengths considered). The acceleration is strong because of relativistic stabilisation of the nonlinearly saturated electrostatic wave, seen in both relativistic Vlasov and PIC simulations. An inverse power law momentum distribution can arise for the most strongly accelerated electrons. These results are of relevance to observed rapid changes in the radio synchrotron emission intensities from microquasars, gamma ray bursts and other astrophysical objects that require rapid acceleration mechanisms for electrons.PACS numbers: 98.54. Aj, 98.58.Mj, 52.35.Mw,52.35.Sb,52.65.Ff,52.65.Rr † On leave from the

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Electrostatic pair creation and recombination in quantum plasmas

et al. 2006

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M. Parviainen

Instability and dynamics of two nonlinearly coupled laser beams in a plasma

Electron surfing acceleration in oblique magnetic fields

Numerical simulation and visualization of stochastic and ordered electron motion forced by electrostatic waves in a magnetized plasma

Phase speed of electrostatic waves: the critical parameter for efficient electron surfing acceleration

Electrostatic pair creation and recombination in quantum plasmas

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