Your search keyword '"Pe'er, Asaf"' showing total 7 results

1. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

2. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

3. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

4. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

5. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

6. Change of a Weibel-type to an Alfvénic shock in pair plasma by upstream waves

Author

Dieckmann, Mark E, Riordan, J D, Pe'er, Asaf, Dieckmann, Mark E, Riordan, J D, and Pe'er, Asaf

Abstract

We examine with particle-in-cell simulations how a parallel shock in pair plasma reacts to upstream waves, which are driven by escaping downstream particles. Initially, the shock is sustained in the two-dimensional simulation by a magnetic filamentation (beam-Weibel) instability. Escaping particles drive an electrostatic beam instability upstream. Modifications of the upstream plasma by these waves hardly affect the shock. In time, a decreasing density and an increasing temperature of the escaping particles quench the beam instability. A larger thermal energy along than perpendicular to the magnetic field destabilizes the pair-Alfvén mode. In the rest frame of the upstream plasma, the group velocity of the growing pair-Alfvén waves is below that of the shock and the latter catches up with the waves. Accumulating pair-Alfvén waves gradually change the shock in the two-dimensional simulation from a Weibel-type shock into an Alfvénic shock with a Mach number that is about 6 for our initial conditions., Funding agencies: EU via the ERC Grant; National Science FoundationNational Science Foundation (NSF) [NSF PHY-1748958]; KITP at Santa Barbara

Published

2020

7. Departure from MHD prescriptions in shock formation over a guiding magnetic field

Author

Bret, Antoine, Pe'er, Asaf, Sironi, Lorenzo, Dieckmann, Mark E, Narayan, Ramesh, Bret, Antoine, Pe'er, Asaf, Sironi, Lorenzo, Dieckmann, Mark E, and Narayan, Ramesh

Abstract

In plasmas where the mean-free-path is much larger than the size of the system, shock waves can arise with a front much shorter than the mean-free path. These so-called "collisionless shocks" are mediated y collective plasma interactions. Studies conducted so far on these shocks found that although binary collisions are absent, the distribution functions are thermalized downstream by scattering on the fields, so that magnetohydrodynamic prescriptions may apply. Here we show a clear departure from this pattern in the case of Weibel shocks forming over a flow-aligned magnetic field. A micro-physical analysis of the particle motion in the Weibel filaments shows how they become unable to trap the flow in the presence of too strong a field, inhibiting the mechanism of shock formation. Particle-in-cell simulations confirm these results., Funding agencies: European Union Seventh Framework Program [618499]; NASA [NNX12AO83G, TCAN NNX14AB47G, NAS8-03060]; NASA - Chandra X-ray Center [PF4-150126]; [ENE2013-45661-C2-1-P]; [PEII-2014-008-P]; [ANR-14-CE33-0019 MACH]; [SNIC2015-1-305]

Published

2017