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Ion Bernstein instability dependence on the proton-to-electron mass ratio: Linear dispersion theory


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dc.contributorKyungguk Min, kyungguk.min@jhuapl.eduen_US
dc.creatorMin, Kyungguk
dc.creatorLiu, Kaijun
dc.date.accessioned2022-10-04T15:32:54Z
dc.date.available2022-10-04T15:32:54Z
dc.date.created2016
dc.identifier10.1002/2016JA022850en_US
dc.identifier.urihttps://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2016JA022850en_US
dc.identifier.urihttps://aurora.auburn.edu/handle/11200/50374
dc.identifier.urihttp://dx.doi.org/10.35099/aurora-442
dc.description.abstractFast magnetosonic waves, which have as their source ion Bernstein instabilities driven by tenuous ring-like proton velocity distributions, are frequently observed in the inner magnetosphere. One major difficulty in the simulation of these waves is that they are excited in a wide frequency range with discrete harmonic nature and require time-consuming computations. To overcome this difficulty, recent simulation studies assumed a reduced proton-to-electron mass ratio, m(p)/m(e), and a reduced light-to-Alfven speed ratio, c/v(A), to reduce the number of unstable modes and, therefore, computational costs. Although these studies argued that the physics of wave-particle interactions would essentially remain the same, detailed investigation of the effect of this reduced system on the excited waves has not been done. In this study, we investigate how the complex frequency, = (r)+i, of the ion Bernstein modes varies with m(p)/m(e) for a sufficiently large c/v(A) (such that pe2</mml:msubsup>/e2</mml:msubsup>(me/mp)(c/vA)2 >> 1) using linear dispersion theory assuming two different types of energetic proton velocity distributions, namely, ring and shell. The results show that low- and high-frequency harmonic modes respond differently to the change of m(p)/m(e). For the low harmonic modes (i.e., (r)approximate to(p)), both (r)/(p) and /(p) are roughly independent of m(p)/m(e), where (p) is the proton cyclotron frequency. For the high harmonic modes (i.e., p<<<mml:msub>r less than or similar to<mml:msub>lh, where (lh) is the lower hybrid frequency), /(lh) (at fixed (r)/(lh)) stays independent of m(p)/m(e) when the parallel wave number, k(vertical bar), is sufficiently large and becomes inversely proportional to (m(p)/m(e))(1/4) when k(vertical bar) goes to zero. On the other hand, the frequency range of the unstable modes normalized to (lh) remains independent of m(p)/m(e), regardless of k(vertical bar).en_US
dc.formatPDFen_US
dc.relation.ispartofseries2169-9380en_US
dc.rights©American Geophysical Union 2016. This is this the version of record co-published by the American Geophysical Union and John Wiley & Sons, Inc. It is made available under the CC-BY-NC-ND 4.0 license. Item should be cited as: Min, Kyungguk, and Kaijun Liu. "Ion Bernstein instability dependence on the proton‐to‐electron mass ratio: Linear dispersion theory." Journal of Geophysical Research: Space Physics 121.7 (2016): 6692-6710.en_US
dc.titleIon Bernstein instability dependence on the proton-to-electron mass ratio: Linear dispersion theoryen_US
dc.typeTexten_US
dc.type.genreJournal Article, Academic Journalen_US
dc.citation.volume121en_US
dc.citation.issue7en_US
dc.citation.spage6692en_US
dc.citation.epage6710en_US
dc.description.statusPublisheden_US
dc.description.peerreviewYesen_US
dc.creator.orcid0000-0001-5882-1328en_US

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