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

Dieckmann, Mark E; Sircombe, N J; Parviainen, M.; Shukła, P. K.; Dendy, R. O.

doi:10.1088/0741-3335/48/4/002

Cited by 11 publications

(12 citation statements)

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“…This is a consequence of the sideband and coalescence instabilities, that limit the life-time of the saturated ES wave. For relativistic proton beam speeds, however, the ES waves stabilize [64], resulting in efficient electron surfing acceleration [44]. The stability of the ES waves is demonstrated by figure 3, which shows the modulus of the ES wave fields that are driven by two counterpropagating proton beams.…”

Section: The Mildly Relativistic Two-stream Instability In Magnetized...mentioning

confidence: 97%

“…We demonstrate how a shock and the shock-reflected ion beam form, if two plasma slabs collide at a superAlfvenic speed perpendicularly to the ambient magnetic field. We discuss the interaction of the shock-reflected proton beam with the upstream plasma [32,33,[39][40][41][42][43] and, in particular, we demonstrate that electrons can be accelerated to high energies by two-stream instabilities and wakefield acceleration and that they can develop power law distributions due to their interaction with an ambient magnetic field [44] in section 3 and electrostatic (ES) turbulence [45][46][47] in section 4. Such processes can exist in the presence of a strong guiding magnetic field, a high plasma temperature and a moderately relativistic flow speed, since then the competing relativistic Weibel instability is suppressed [48][49][50].…”

Section: Introductionmentioning

confidence: 99%

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Two-stream instability in collisionless shocks and foreshock

Dieckmann

Eliasson

Shukła

et al. 2006

Plasma Phys. Control. Fusion

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Shocks play a key role in plasma thermalization and particle acceleration in the near Earth space plasma, in astrophysical plasma and in laser plasma interactions. An accurate understanding of the physics of plasma shocks is thus of immense importance. We give an overview over some recent developments in particle-in-cell simulations of plasma shocks and foreshock dynamics. We focus on ion reflection by shocks and on the two-stream instabilities these beams can drive, and these are placed in the context of experimental observations, e.g. by the Cluster mission. We discuss how we may expand the insight gained from the observation of proton beam driven instabilities at near Earth plasma shocks to better understand their astrophysical counterparts, such as ion beam instabilities triggered by internal and external shocks in the relativistic jets of gamma ray bursts, shocks in the accretion discs of micro-quasars and supernova remnant shocks. It is discussed how and why the peak energy that can be reached by particles that are accelerated by two-stream instabilities increases from keV energies to GeV energies and beyond, as we increase the streaming speed to relativistic values, and why the particle energy spectrum sometimes resembles power law distributions.

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Section: The Mildly Relativistic Two-stream Instability In Magnetized...mentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Two-stream instability in collisionless shocks and foreshock

Dieckmann

Eliasson

Shukła

et al. 2006

Plasma Phys. Control. Fusion

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“…Early in 1983, Dawson et al [14,15] showed electrons can be accelerated when they are trapped in EPWs propagating perpendicular to a magnetic field, and meanwhile the EPWs heavily damped. The use of transverse external magnetic fields in plasma has been extensively studied in particle acceleration [16,17], but there are only a few studies [18] on the nonlinear damping mechanism. Winjum et al [19] showed that, in the kinetic regime, a transverse magnetic field with tens of tesla can significantly reduce backward stimulated Raman scattering (BSRS) reflectivity.…”

Section: Introductionmentioning

confidence: 99%

Suppression of autoresonant stimulated Raman scattering in transversely weakly magnetized plasmas

Zhou

Zheng

Liu

et al. 2021

Plasma Phys. Control. Fusion

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We investigate the behaviour of backward stimulated Raman scattering (BSRS) in inhomogeneous plasma with a transverse external magnetic field via 1D and 2D particle-in-cell simulations and theoretical analysis. The external magnetic field B e x t causes nonlinear damping of large-amplitude electron plasma waves (EPWs), and significantly limits the reflectivity of stimulated Raman scattering (SRS) even if B e x t is very weak. For a single resonance point, B e x t limits the kinetic nonlinear frequency shift, impedes the autoresonance behaviour of SRS, and narrows the resonance region. We also exhibit B e x t distorts the distribution function of electrons evidently, and alters the wavefronts of EPWs in high dimensional cases. The simulation results indicate a moderate B e x t can significantly reduce the trapped electron induced gain of SRS reflectivity, and make the BSRS reflectivity stay at its linear convective saturation level steadily.

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“…Here, we suggest that at least some of the features of early afterglows can be related to complex shock physics and/or features in the fireball/jet. In fact, simulations of the acceleration of electrons and positrons by the first and second Fermi processes show that the evolution of electric and magnetic fields as well as the energy distribution of accelerated particles are quite complex (Bednarz & Ostrowski 1996; Dieckmann et al 2006; Rieger, Bosch‐Ramon & Duffy 2007). Plasma instabilities lead to the formation of coherent electric and magnetic fields and acceleration of particles (Yang, Arnos & Langdon 1994; Silva et al 2002; Wiersma & Achterberg 2004; Reville, Kirk & Duffy 2006).…”

Section: Introductionmentioning

confidence: 99%

A systematic description of shocks in gamma-ray bursts - I. Formulation

Ziaeepour¹

2009

Monthly Notices of the Royal Astronomical Society

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Since the suggestion of relativistic shocks as the origin of gamma-ray bursts (GRBs) in the early 1990s, the mathematical formulation of this process has stayed at a phenomenological level. One of the reasons for the slow development of theoretical works has been the simple power-law behaviour of the afterglows hours or days after the prompt gamma-ray emission. It was believed that they could be explained with these formulations. Nowadays, with the launch of the Swift satellite and implementation of robotic ground follow-ups, GRBs and their afterglow can be observed at multi-wavelengths from a few tens of seconds after trigger onwards. These observations have led to the discovery of features unexplainable by the simple formulation of the shocks and emission processes used up to now. Some of these features can be inherent in the nature and activities of the GRBs' central engines which are not yet well understood. On the other hand, the devil is in the detail and others may be explained with a more detailed formulation of these phenomena and without ad hoc addition of new processes. Such a formulation is the goal of this work. We present a consistent formulation of the kinematics and dynamics of the collision between two spherical relativistic shells, their energy dissipation and their coalescence. It can be applied to both internal and external shocks. Notably, we propose two phenomenological models for the evolution of the emitting region during the collision. One of these models is more suitable for the prompt/internal shocks and late external shocks, and the other for the afterglow/external collisions as well as the onset of internal shocks. We calculate a number of observables such as flux, lag between energy bands and hardness ratios. One of our aims has been a formulation complex enough to include the essential processes, but simple enough such that the data can be directly compared with the theory to extract the value and evolution of physical quantities. To accomplish this goal, we also suggest a procedure for extracting parameters of the model from data. In a companion paper, we numerically calculate the evolution of some simulated models and compare their features with the properties of the observed GRBs.

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

Cited by 11 publications

References 50 publications

Two-stream instability in collisionless shocks and foreshock

Two-stream instability in collisionless shocks and foreshock

Suppression of autoresonant stimulated Raman scattering in transversely weakly magnetized plasmas

A systematic description of shocks in gamma-ray bursts - I. Formulation

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