Your search keyword '"S. Matsukiyo"' showing total 4 results

1. Acceleration of Relativistic Particles in Counterpropagating Circularly Polarized Alfvén Waves

Author

S. Isayama, K. Takahashi, S. Matsukiyo, and T. Sano

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Abstract

Counterpropagating Alfvén waves are ubiquitously observed in many astrophysical environments, such as a star surface and a planetary foreshock. We discuss an efficient particle acceleration mechanism in two counterpropagating circularly polarized Alfvén waves. Phase transitions of particle behavior occur when wave amplitudes exceed two critical values. Above the critical amplitudes, the numerical simulation shows that any particles irreversibly gain relativistic energy within a short time regardless of their initial position and energy once the coherent waveform is formed. The accelerated particles have spatial coherence. Higher wave phase velocity requires smaller critical amplitudes, while the maximum attainable energy increases as the wavenumber and the frequency decrease. The results may be applicable in some astrophysical phenomena, as well as a future laboratory experiment using high-power lasers.

Published

2023

2. Non-stationarity of the quasi-perpendicular bow shock: comparison between Cluster observations and simulations

Author

H. Comişel, M. Scholer, J. Soucek, and S. Matsukiyo

Subjects

Shock wave, Atmospheric Science, Whistler, Astrophysics::High Energy Astrophysical Phenomena, Optics, Earth and Planetary Sciences (miscellaneous), Bow shock (aerodynamics), lcsh:Science, Physics, Shock (fluid dynamics), business.industry, lcsh:QC801-809, Geology, Astronomy and Astrophysics, lcsh:QC1-999, Computational physics, Solar wind, lcsh:Geophysics. Cosmic physics, Space and Planetary Science, Physics::Space Physics, Reflection (physics), Oblique shock, lcsh:Q, Phase velocity, business, lcsh:Physics

Abstract

We have performed full particle electromagnetic simulations of a quasi-perpendicular shock. The shock parameters have been chosen to be appropriate for the quasi-perpendicular Earth's bow shock observed by Cluster on 24 January 2001 (Lobzin et al., 2007). We have performed two simulations with different ion to electron mass ratio: run 1 with mi/me=1840 and run 2 with mi/me=100. In run 1 the growth rate of the modified two-stream instability (MTSI) is large enough to get excited during the reflection and upstream gyration of part of the incident solar wind ions. The waves due to the MTSI are on the whistler mode branch and have downstream directed phase velocities in the shock frame. The Poynting flux (and wave group velocity) far upstream in the foot is also directed in the downstream direction. However, in the density and magnetic field compression region of the overshoot the waves are refracted and the Poynting flux in the shock frame is directed upstream. The MTSI is suppressed in the low mass ratio run 2. The low mass ratio run shows more clearly the non-stationarity of the shock with a larger time scale of the order of an inverse ion gyrofrequency (Ωci): the magnetic field profile flattens and steepens with a period of ~1.5Ωci−1. This non-stationarity is different from reformation seen in previous simulations of perpendicular or quasi-perpendicular shocks. Beginning with a sharp shock ramp the large electric field in the normal direction leads to high reflection rate of solar wind protons. As they propagate upstream, the ion bulk velocity decreases and the magnetic field increases in the foot, which results in a flattening of the magnetic field profile and in a decrease of the normal electric field. Subsequently the reflection rate decreases and the whole shock profile steepens again. Superimposed on this 'breathing' behavior are in the realistic mass ratio case the waves due to the MTSI. The simulations lead us to a re-interpretation of the 24 January 2001 bow shock observations reported by Lobzin et al. (2007). It is suggested that the high frequency waves observed in the magnetic field data are due to the MTSI and are not related to a nonlinear phase standing whistler. Different profiles at the different spacecraft are due to the non-stationary behavior on the larger time scale.

Published

2011

3. Relativisitic particle acceleration in developing Alfve´n turbulence

Author

T. Hada and S. Matsukiyo

Subjects

Physics, relativity, Turbulence, turbulence, Astronomy and Astrophysics, Plasma, plasmas, Resonance (particle physics), Relativistic particle, Computational physics, Particle acceleration, Acceleration, Astrophysics - Solar and Stellar Astrophysics, cosmic rays, Space and Planetary Science, Particle, waves, Astrophysics - High Energy Astrophysical Phenomena, Energy (signal processing), acceleration of particles

Abstract

A new particle acceleration process in a developing Alfv\'{e}n turbulence in the course of successive parametric instabilities of a relativistic pair plasma is investigated by utilyzing one-dimensional electromagnetic full particle code. Coherent wave-particle interactions result in efficient particle acceleration leading to a power-law like energy distribution function. In the simulation high energy particles having large relativistic masses are preferentially accelerated as the turbulence spectrum evolves in time. Main acceleration mechanism is simultaneous relativistic resonance between a particle and two different waves. An analytical expression of maximum attainable energy in such wave-particle interactions is derived., Comment: 15 pages, 9 figures, 1 table

Published

2009

4. Pickup protons at quasi-perpendicular shocks: full particle electrodynamic simulations

Author

S. Matsukiyo, M. Scholer, D. Burgess, Department of Earth System Science and Technology [Fukuoka] (ESST), Kyushu University [Fukuoka], Astronomy Unit [London] (AU), Queen Mary University of London (QMUL), and EGU, Publication

Subjects

Shock wave, Atmospheric Science, 010504 meteorology & atmospheric sciences, Proton, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Electron, 01 natural sciences, Moving shock, symbols.namesake, Optics, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), lcsh:Science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Physics, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, business.industry, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, lcsh:QC801-809, Geology, Astronomy and Astrophysics, Mechanics, lcsh:QC1-999, Shock (mechanics), Particle acceleration, lcsh:Geophysics. Cosmic physics, Mach number, Space and Planetary Science, symbols, [SDU.STU] Sciences of the Universe [physics]/Earth Sciences, Oblique shock, lcsh:Q, business, lcsh:Physics

Abstract

We have performed 3 one-dimensional full particle electromagnetic simulations of a quasi-perpendicular shock with the same Alfvén Mach number MA~5, shock normal-magnetic field angle ΘBn=87° and ion and electron beta (particle to magnetic field pressure) of 0.1. In the first run we used an ion to electron mass ratio close to the physical one (mi/me=1024). As expected from previous high mass ratio simulations the Modified Two-Stream instability develops in the foot of the shock, and the shock periodically reforms itself. We have then self-consistently included in the simulation 10% pickup protons distributed on a shell in velocity space as a third component. In a run with an unrealistically low mass ratios of 200 the shock still reforms itself; reformation is due to accumulation of specularly reflected particles at the upstream edge of the foot. In a third run including pickup protons we used a mass ratio of 1024. The shock reforms periodically as in the low mass ratio run with a somewhat smaller time constant. The specular reflection of pickup protons results in an increase of the shock potential some distance ahead of the shock foot and ramp. The minimum scale of the cross shock potential during reformation is about 7 electron inertial length λe. We do not find any pickup proton acceleration in the ramp or downstream of the shock beyond the energy which specularly reflected ions gain by the motional electric field of the solar wind during their upstream gyration.

Published

2007