Empirical selection of Auroral Kilometric Radiation during a multipoint remote observation with Wind and Cassini
Empirical selection of Auroral Kilometric Radiation during a multipoint remote observation with Wind and Cassini
Auroral Kilometric Radiation (AKR) is terrestrial radio emission that originates in particle acceleration regions along magnetic field lines, coinciding with discrete auroral arcs. AKR viewing geometry is complex due to the confinement of the source regions to nightside local times (LTs) and the anisotropy of the beaming pattern, so observations are highly dependent on spacecraft viewing position. We present a novel, empirical technique that selects AKR emission from observations made with the spin-axis aligned antenna of the Wind/WAVES instrument, based on the rapidly varying amplitude of AKR across spacecraft spin timescales. We apply the technique to Wind/WAVES data during 1999 day of year 227–257, when the Cassini spacecraft flew past Earth and provided an opportunity to observe AKR from two remote locations. We examine the AKR flux and power, with observations made from LTs of 1700–0300 hr having an average power up to 10
4 Wsr
-1 larger than those on the dayside and an increasing AKR power observed at higher magnetic latitudes. We perform a linear cross-correlation between the Wind AKR power and the spacecraft magnetic latitude, showing positive then negative correlation as Wind travels from the Northern to Southern magnetic hemisphere. Statistically significant diurnal modulations are found in the whole 30-day period and in subsets of the data covering different local time sectors, indicative of a predominantly geometrical effect for remote AKR viewing. The reproduction of well-known features of the AKR verifies the empirical selection and shows the promise of its application to Wind/WAVES observations.
auroral kilometric radiation, cassini, multipoint observation, radio astronomy, remote sensing, wind
Waters, James
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Jackman, Caitriona
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Lamy, Laurent
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Cecconi, Baptiste
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Whiter, Daniel
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Bonnin, Xavier
19da5602-2dac-4fad-a0fe-bde2683fda37
Issautier, Karine
9354fb42-cb07-4125-90a4-01c4cc20da5c
Fogg, Alexandra
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18 October 2021
Waters, James
7e6a7887-ad91-4b04-963e-48c734e778ed
Jackman, Caitriona
4c74323d-b410-48da-adf1-2207169696ab
Lamy, Laurent
be890ca9-445a-4fd9-8572-be416f007250
Cecconi, Baptiste
a33a7bf9-2bf2-4c61-809b-ba1ea19fd65d
Whiter, Daniel
9a30d7b6-ea41-44fb-bd52-3ff1964eca5c
Bonnin, Xavier
19da5602-2dac-4fad-a0fe-bde2683fda37
Issautier, Karine
9354fb42-cb07-4125-90a4-01c4cc20da5c
Fogg, Alexandra
aea16623-279d-423a-85a3-c95868c0863d
Waters, James, Jackman, Caitriona, Lamy, Laurent, Cecconi, Baptiste, Whiter, Daniel, Bonnin, Xavier, Issautier, Karine and Fogg, Alexandra
(2021)
Empirical selection of Auroral Kilometric Radiation during a multipoint remote observation with Wind and Cassini.
Journal of Geophysical Research: Space Physics, 126 (10), [e2021JA029425].
(doi:10.1029/2021JA029425).
Abstract
Auroral Kilometric Radiation (AKR) is terrestrial radio emission that originates in particle acceleration regions along magnetic field lines, coinciding with discrete auroral arcs. AKR viewing geometry is complex due to the confinement of the source regions to nightside local times (LTs) and the anisotropy of the beaming pattern, so observations are highly dependent on spacecraft viewing position. We present a novel, empirical technique that selects AKR emission from observations made with the spin-axis aligned antenna of the Wind/WAVES instrument, based on the rapidly varying amplitude of AKR across spacecraft spin timescales. We apply the technique to Wind/WAVES data during 1999 day of year 227–257, when the Cassini spacecraft flew past Earth and provided an opportunity to observe AKR from two remote locations. We examine the AKR flux and power, with observations made from LTs of 1700–0300 hr having an average power up to 10
4 Wsr
-1 larger than those on the dayside and an increasing AKR power observed at higher magnetic latitudes. We perform a linear cross-correlation between the Wind AKR power and the spacecraft magnetic latitude, showing positive then negative correlation as Wind travels from the Northern to Southern magnetic hemisphere. Statistically significant diurnal modulations are found in the whole 30-day period and in subsets of the data covering different local time sectors, indicative of a predominantly geometrical effect for remote AKR viewing. The reproduction of well-known features of the AKR verifies the empirical selection and shows the promise of its application to Wind/WAVES observations.
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More information
Accepted/In Press date: 28 September 2021
e-pub ahead of print date: 6 October 2021
Published date: 18 October 2021
Keywords:
auroral kilometric radiation, cassini, multipoint observation, radio astronomy, remote sensing, wind
Identifiers
Local EPrints ID: 453172
URI: http://eprints.soton.ac.uk/id/eprint/453172
ISSN: 2169-9402
PURE UUID: 07af6ec2-22d2-43d1-97be-34781a3eb351
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Date deposited: 10 Jan 2022 17:56
Last modified: 17 Mar 2024 03:14
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Contributors
Author:
James Waters
Author:
Caitriona Jackman
Author:
Laurent Lamy
Author:
Baptiste Cecconi
Author:
Xavier Bonnin
Author:
Karine Issautier
Author:
Alexandra Fogg
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