2020
DOI: 10.3847/2041-8213/ab75f4
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Laboratory Observations of Ultra-low-frequency Analog Waves Driven by the Right-hand Resonant Ion Beam Instability

Abstract: The right-hand resonant instability (RHI) is one of several electromagnetic ion/ion beam instabilities responsible for the formation of parallel magnetized collisionless shocks and the generation of ultra-low frequency (ULF) waves in their foreshocks. This instability has been observed for the first time under foreshock-relevant conditions in the laboratory through the repeatable interaction of a pre-formed magnetized background plasma and a super-Alfvénic laser-produced plasma. This platform has enabled unpre… Show more

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Cited by 18 publications
(13 citation statements)
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“…[20][21][22][23][24][25][26][27][28] Space measurements (Ref. 29 and references therein) as well as laboratory experiments 30 have been observing these predicted waves. Also, in a steepened wave structure such as SLAMS (short, large-amplitude magnetic structures), 31 high-frequency waves such as whistler waves can be generated 27,32 (for space observations, see Ref.…”
Section: Introductionmentioning
confidence: 94%
“…[20][21][22][23][24][25][26][27][28] Space measurements (Ref. 29 and references therein) as well as laboratory experiments 30 have been observing these predicted waves. Also, in a steepened wave structure such as SLAMS (short, large-amplitude magnetic structures), 31 high-frequency waves such as whistler waves can be generated 27,32 (for space observations, see Ref.…”
Section: Introductionmentioning
confidence: 94%
“…Test cases using an adiabatic electron equation of state (penγ with γ=5/3) showed little difference in the bulk dynamics of our simulations, which is primarily controlled by the electromagnetic coupling between the debris and background ions. Similar hybrid models have been used previously to study general astrophysical explosions (Bashurin et al., 1983; Brecht et al., 2009; Hewett et al., 2011; Winske & Gary, 2007) and shocks (Lembège & Simonet, 2001; Thomas & Brecht, 1986), as well as problems related to chemical releases in the magnetosphere (Bernhardt et al., 1987; Delamere et al., 1999) and laser‐driven laboratory experiments (Clark et al., 2013; Heuer et al., 2020; Weidl et al., 2016).…”
Section: Hybrid Simulationsmentioning
confidence: 99%
“…Debris ions moving mainly parallel to the background magnetic field couple weakly to the ambient plasma. Rather than coupling through the Larmor mechanism (Bashurin et al., 1983; Golubev et al., 1978), the parallel‐streaming ions couple to the background primarily through ion‐ion beam instabilities (Gary et al., 1984; Heuer et al., 2020; Weidl et al., 2019). This coupling is comparatively weak, and in all our cases, a population of ions streams nearly freely from the explosion for at least several hundred ion inertial lengths.…”
Section: Free‐streaming Ion Beamsmentioning
confidence: 99%
“…Test cases using an adiabatic electron equation of state (p e ∝ n γ with γ = 5/3) showed little difference in the bulk dynamics of our simulations, which is primarily controlled by the electromagnetic coupling between the debris and background ions. Similar hybrid models have been used previously to study general astrophysical explosions (Bashurin et al, 1983;Winske & Gary, 2007;Brecht et al, 2009;Hewett et al, 2011) and shocks (Thomas & Brecht, 1986;Lembège & Simonet, 2001), as well as problems related to chemical releases in the magnetosphere (Bernhardt et al, 1987;Delamere et al, 1999) and laser-driven laboratory experiments (Clark et al, 2013;Weidl et al, 2016;Heuer et al, 2020).…”
Section: Hybrid Simulationsmentioning
confidence: 99%