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Interchange Injections at Saturn: Statistical Survey of Energetic H + Sudden Flux Intensifications
Author(s) -
Azari Abigail R.,
Liemohn Michael W.,
Jia Xianzhe,
Thomsen Michelle F.,
Mitchell Donald G.,
Sergis Nick,
Rymer Abigail M.,
Hospodarsky George B.,
Paranicas Christopher,
Vandegriff Jon
Publication year - 2018
Publication title -
journal of geophysical research: space physics
Language(s) - English
Resource type - Journals
eISSN - 2169-9402
pISSN - 2169-9380
DOI - 10.1029/2018ja025391
Subject(s) - saturn , magnetosphere , flux (metallurgy) , ionosphere , physics , local time , intensity (physics) , event (particle physics) , range (aeronautics) , computational physics , geophysics , planet , astronomy , astrophysics , nuclear physics , aerospace engineering , chemistry , statistics , optics , plasma , mathematics , organic chemistry , engineering
Abstract We present a statistical study of interchange injections in Saturn's inner and middle magnetosphere focusing on the dependence of occurrence rate and properties on radial distance, partial pressure, and local time distribution. Events are evaluated from over the entirety of the Cassini mission's equatorial orbits between 2005 and 2016. We identified interchange events from CHarge Energy Mass Spectrometer (CHEMS) H + data using a trained and tested automated algorithm, which has been compared with manual event identification for optimization. We provide estimates of interchange based on intensity, which we use to investigate current inconsistencies in local time occurrence rates. This represents the first automated detection method of interchange, estimation of injection event intensity, and comparison between interchange injection survey results. We find that the peak rates of interchange occur between 7 and 9 Saturn radii and that this range coincides with the most intense events as defined by H + partial particle pressure. We determine that nightside occurrence dominates as compared to the dayside injection rate, supporting the hypothesis of an inversely dependent instability growth rate on local Pedersen ionospheric conductivity. Additionally, we observe a slight preference for intense events on the dawnside, supporting a triggering mechanism related to large‐scale injections from downtail reconnection. Our observed local time dependence paints a dynamic picture of interchange triggering due to both the large‐scale injection‐driven process and ionospheric conductivity.