Drivers of magnetic field amplification at oblique shocks: in-situ observations
Drivers of magnetic field amplification at oblique shocks: in-situ observations
Collisionless shocks are ubiquitous structures throughout the universe. Shock waves in space and astrophysical plasmas convert the energy of a fast-flowing plasma to other forms of energy, including thermal and magnetic energies. Plasma turbulence and high-amplitude electric and magnetic fluctuations are necessary for effective energy conversion and particle acceleration. We survey and characterize in-situ observations of reflected ions and magnetic field amplification rates at quasi-perpendicular shocks under a wide range of upstream conditions. We report magnetic amplification factors as high as 25 times the upstream magnetic field in our current dataset. Reflected ions interacting with the incoming plasma create magnetic perturbations which cause magnetic amplification in upstream and downstream regions of quasi-perpendicular shocks. Our observations show that in general magnetic amplification increases with the fraction of reflected ions, which itself increases with Mach number. Both parameters plateau once full reflection is reached. Magnetic amplification continuously increases with the inverse of the magnetization parameter of the upstream plasma. We find that the extended foot region upstream of shocks and nonlinear processes within that region are key factors for intense magnetic amplification. Our observations at non-relativistic shocks provide the first experimental evidence that below a certain magnetization threshold, the magnetic amplification efficiency at quasi-perpendicular shocks becomes comparable to that at the quasi-parallel shocks.
physics.plasm-ph
Madanian, Hadi
5ccd860a-5114-4f20-86f0-f9330bdcf06c
Gingell, Imogen
ba7b8113-3833-40d8-a879-aab3f987455d
Chen, Li-Jen
0b23e006-0d61-4090-9260-2411673811d0
Monyek, Eli
51346ee4-5bdd-494f-9231-d34467d1fde1
Madanian, Hadi
5ccd860a-5114-4f20-86f0-f9330bdcf06c
Gingell, Imogen
ba7b8113-3833-40d8-a879-aab3f987455d
Chen, Li-Jen
0b23e006-0d61-4090-9260-2411673811d0
Monyek, Eli
51346ee4-5bdd-494f-9231-d34467d1fde1
[Unknown type: UNSPECIFIED]
Abstract
Collisionless shocks are ubiquitous structures throughout the universe. Shock waves in space and astrophysical plasmas convert the energy of a fast-flowing plasma to other forms of energy, including thermal and magnetic energies. Plasma turbulence and high-amplitude electric and magnetic fluctuations are necessary for effective energy conversion and particle acceleration. We survey and characterize in-situ observations of reflected ions and magnetic field amplification rates at quasi-perpendicular shocks under a wide range of upstream conditions. We report magnetic amplification factors as high as 25 times the upstream magnetic field in our current dataset. Reflected ions interacting with the incoming plasma create magnetic perturbations which cause magnetic amplification in upstream and downstream regions of quasi-perpendicular shocks. Our observations show that in general magnetic amplification increases with the fraction of reflected ions, which itself increases with Mach number. Both parameters plateau once full reflection is reached. Magnetic amplification continuously increases with the inverse of the magnetization parameter of the upstream plasma. We find that the extended foot region upstream of shocks and nonlinear processes within that region are key factors for intense magnetic amplification. Our observations at non-relativistic shocks provide the first experimental evidence that below a certain magnetization threshold, the magnetic amplification efficiency at quasi-perpendicular shocks becomes comparable to that at the quasi-parallel shocks.
Text
2402.02014v1
- Author's Original
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Accepted/In Press date: 3 February 2024
Keywords:
physics.plasm-ph
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Local EPrints ID: 487363
URI: http://eprints.soton.ac.uk/id/eprint/487363
PURE UUID: 4869cbc3-23d3-4b37-8d9e-c720696ccec2
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Date deposited: 20 Feb 2024 00:01
Last modified: 18 Mar 2024 03:55
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Contributors
Author:
Hadi Madanian
Author:
Li-Jen Chen
Author:
Eli Monyek
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