Your search keyword '"Luis Preisser"' showing total 2 results

1. Interplanetary Magnetic Flux Rope Observed at Ground Level by HAWC

Author

J. R. Angeles Camacho, A. Iriarte, Nissim Fraija, James Ryan, J. Martínez-Castro, Luis Villaseñor, J.C. Arteaga-Velázquez, D. Garcia, Tatiana Niembro, E. Moreno, F. Salesa Greus, John Matthews, Luis Preisser, Alejandro Lara, E. G. Pérez-Pérez, J. P. Harding, U. Cotti, K. Malone, T. Capistrán, G. Luis-Raya, A. Carramiñana, D. Avila Rojas, E. De la Fuente, M. Newbold, Amid Nayerhoda, Maria Magdalena González, Teresa Nieves-Chinchilla, B. Hona, Filiberto Hueyotl-Zahuantitla, A. Galván-Gámez, Sabrina Casanova, P. Miranda-Romagnoli, V. Joshi, K. P. Arunbabu, E. Belmont-Moreno, R. Noriega-Papaqui, Jose Andres Garcia-Gonzalez, Ruben Alfaro, I. Torres, Sachiko Akiyama, C. D. Rho, Gerd J. Kunde, D. Huang, J. Cotzomi, Karen S. Caballero-Mora, Catalina Espinoza, H. A. Ayala Solares, C. De León, F. Garfias, R. Diaz Hernandez, Arnulfo Zepeda, A. Sandoval, F. Ureña-Mena, H. León Vargas, Lukas Nellen, R. W. Springer, H. Salazar, C. Alvarez, David Kieda, P. Hüntemeyer, J. A. Goodman, and P. Colin-Farias

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Geomagnetic storm, 010504 meteorology & atmospheric sciences, Turbulence, FOS: Physical sciences, Flux, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Magnetic flux, Physics::Geophysics, Magnetic field, Earth's magnetic field, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, Coronal mass ejection, Astrophysics::Solar and Stellar Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Interplanetary spaceflight, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), 0105 earth and related environmental sciences

Abstract

We report the ground-level detection of a Galactic Cosmic-Ray (GCR) flux enhancement lasting $\sim$ 17 hr and associated with the passage of a magnetic flux rope (MFR) over the Earth. The MFR was associated with a slow Coronal Mass Ejection (CME) caused by the eruption of a filament on 2016 October 9. Due to the quiet conditions during the eruption and the lack of interactions during the interplanetary CME transport to the Earth, the associated MFR preserved its configuration and reached the Earth with a strong magnetic field, low density, and a very low turbulence level compared to the local background, thus generating the ideal conditions to redirect and guide GCRs (in the $\sim$ 8 to 60 GV rigidity range) along the magnetic field of the MFR. An important negative $B_Z$ component inside the MFR caused large disturbances in the geomagnetic field and a relatively strong geomagnetic storm. However, these disturbances are not the main factors behind the GCR enhancement. Instead, we found that the major factor was the alignment between the MFR axis and the asymptotic direction of the observer.

Published

2020

2. Magnetosheath Jets and Plasmoids: Characteristics and Formation Mechanisms from Hybrid Simulations

Author

Luis Preisser, Domenico Trotta, Primoz Kajdic, Xochitl Blanco-Cano, and David Burgess

Subjects

Physics, Magnetosheath, Space and Planetary Science, Interplanetary medium, Astronomy and Astrophysics, Plasmoid, Plasma, Astrophysics, Space weather, Heliosphere

Abstract

Magnetosheath jets and plasmoids are very common phenomena downstream of Earth’s quasi-parallel bow shock. As the increase of the dynamic pressure is one of the principal characteristics of magnetosheath jets, the embedded paramagnetic plasmoids have been considered as an special case of the former. Although the properties of both types of structures have been widely studied during the last 20 years, their formation mechanisms have not been examined thoroughly. In this work we perform a 2D local hybrid simulation (kinetic ions – fluid electrons) of a quasi-parallel (θ Bn = 15°), supercritical (M A = 7) collisionless shock in order to study these mechanisms. Specifically, we analyze the formation of one jet and one plasmoid, showing for the first time that they can be produced by different mechanisms related to the same shock. In our simulation, the magnetosheath jet is formed according to the mechanism proposed by Hietala, where at the shock ripples the upstream solar wind suffers locally less deceleration and the flow is focused in the downstream side, producing a compressed and high-velocity region that leads to an increase of dynamic pressure downstream of the shock. The formation of the plasmoid, however, follows a completely new scenario being generated by magnetic reconnection between two plasma layers with opposite B-field orientation in the region just behind the shock.

Published

2020