Heating of the sunlit polar cap ionosphere by reflected photoelectrons

Photoelectrons escape from the ionosphere on sunlit polar cap field lines. In order for those field lines to carry zero current without significant heavy ion outflow or cold electron inflow, field-aligned potential drops must form to reflect a portion of the escaping photoelectron population back to...

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Published in:Journal of Geophysical Research: Space Physics
Other Authors: Varney, Roger (author), Solomon, Stanley (author), Nicholls, M. (author)
Format: Article in Journal/Newspaper
Language:English
Published: American Geophysical Union 2014
Subjects:
Resolute Bay
Online Access:http://nldr.library.ucar.edu/repository/collections/OSGC-000-000-021-300
https://doi.org/10.1002/2013JA019378
id ftncar:oai:drupal-site.org:articles_14475
record_format openpolar
spelling ftncar:oai:drupal-site.org:articles_14475 2023-09-05T13:22:49+02:00 Heating of the sunlit polar cap ionosphere by reflected photoelectrons Varney, Roger (author) Solomon, Stanley (author) Nicholls, M. (author) 2014-10-01 application/pdf http://nldr.library.ucar.edu/repository/collections/OSGC-000-000-021-300 https://doi.org/10.1002/2013JA019378 en eng American Geophysical Union Journal of Geophysical Research-Space Physics http://nldr.library.ucar.edu/repository/collections/OSGC-000-000-021-300 doi:10.1002/2013JA019378 ark:/85065/d7r78g6w Copyright 2014 American Geophysical Union. Text article 2014 ftncar https://doi.org/10.1002/2013JA019378 2023-08-14T18:36:21Z Photoelectrons escape from the ionosphere on sunlit polar cap field lines. In order for those field lines to carry zero current without significant heavy ion outflow or cold electron inflow, field-aligned potential drops must form to reflect a portion of the escaping photoelectron population back to the ionosphere. Using a 1-D ionosphere-polar wind model and measurements from the Resolute Bay Incoherent Scatter Radar (RISR-N), this paper shows that these reflected photoelectrons are a significant source of heat for the sunlit polar cap ionosphere. The model includes a kinetic suprathermal electron transport solver, and it allows energy input from the upper boundary in three different ways: thermal conduction, soft precipitation, and potentials that reflect photoelectrons. The simulations confirm that reflection potentials of several tens of eV are required to prevent cold electron inflow and demonstrate that the flux tube integrated change in electron heating rate (FTICEHR) associated with reflected photoelectrons can reach 109eV cm-2s-1. Soft precipitation can produce FTICEHR of comparable magnitudes, but this extra heating is divided among more electrons as a result of electron impact ionization. Simulations with no reflected photoelectrons and with downward field-aligned currents (FAC) primarily carried by the escaping photoelectrons have electron temperatures which are -250-500 K lower than the RISR-N measurements in the 300-600 km region; however, simulations with reflected photoelectrons, zero FAC, and no other form of heat flux through the upper boundary can satisfactorily reproduce the RISR-N data. Article in Journal/Newspaper Resolute Bay OpenSky (NCAR/UCAR - National Center for Atmospheric Research/University Corporation for Atmospheric Research) Resolute Bay ENVELOPE(-94.842,-94.842,74.677,74.677) Journal of Geophysical Research: Space Physics 119 10 8660 8684
institution Open Polar
collection OpenSky (NCAR/UCAR - National Center for Atmospheric Research/University Corporation for Atmospheric Research)
op_collection_id ftncar
language English
description Photoelectrons escape from the ionosphere on sunlit polar cap field lines. In order for those field lines to carry zero current without significant heavy ion outflow or cold electron inflow, field-aligned potential drops must form to reflect a portion of the escaping photoelectron population back to the ionosphere. Using a 1-D ionosphere-polar wind model and measurements from the Resolute Bay Incoherent Scatter Radar (RISR-N), this paper shows that these reflected photoelectrons are a significant source of heat for the sunlit polar cap ionosphere. The model includes a kinetic suprathermal electron transport solver, and it allows energy input from the upper boundary in three different ways: thermal conduction, soft precipitation, and potentials that reflect photoelectrons. The simulations confirm that reflection potentials of several tens of eV are required to prevent cold electron inflow and demonstrate that the flux tube integrated change in electron heating rate (FTICEHR) associated with reflected photoelectrons can reach 109eV cm-2s-1. Soft precipitation can produce FTICEHR of comparable magnitudes, but this extra heating is divided among more electrons as a result of electron impact ionization. Simulations with no reflected photoelectrons and with downward field-aligned currents (FAC) primarily carried by the escaping photoelectrons have electron temperatures which are -250-500 K lower than the RISR-N measurements in the 300-600 km region; however, simulations with reflected photoelectrons, zero FAC, and no other form of heat flux through the upper boundary can satisfactorily reproduce the RISR-N data.
author2 Varney, Roger (author)
Solomon, Stanley (author)
Nicholls, M. (author)
format Article in Journal/Newspaper
title Heating of the sunlit polar cap ionosphere by reflected photoelectrons
spellingShingle Heating of the sunlit polar cap ionosphere by reflected photoelectrons
title_short Heating of the sunlit polar cap ionosphere by reflected photoelectrons
title_full Heating of the sunlit polar cap ionosphere by reflected photoelectrons
title_fullStr Heating of the sunlit polar cap ionosphere by reflected photoelectrons
title_full_unstemmed Heating of the sunlit polar cap ionosphere by reflected photoelectrons
title_sort heating of the sunlit polar cap ionosphere by reflected photoelectrons
publisher American Geophysical Union
publishDate 2014
url http://nldr.library.ucar.edu/repository/collections/OSGC-000-000-021-300
https://doi.org/10.1002/2013JA019378
long_lat ENVELOPE(-94.842,-94.842,74.677,74.677)
geographic Resolute Bay
geographic_facet Resolute Bay
genre Resolute Bay
genre_facet Resolute Bay
op_relation Journal of Geophysical Research-Space Physics
http://nldr.library.ucar.edu/repository/collections/OSGC-000-000-021-300
doi:10.1002/2013JA019378
ark:/85065/d7r78g6w
op_rights Copyright 2014 American Geophysical Union.
op_doi https://doi.org/10.1002/2013JA019378
container_title Journal of Geophysical Research: Space Physics
container_volume 119
container_issue 10
container_start_page 8660
op_container_end_page 8684
_version_ 1776203359477301248

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