C. Baumann, A. Kero, S. Raizada, M. Rapp, M. Sulzer, P. Verronen, J. Vierinen
{"title":"Arecibo measurements of D-region electron densities during sunset and sunrise: implications for atmospheric composition","authors":"C. Baumann, A. Kero, S. Raizada, M. Rapp, M. Sulzer, P. Verronen, J. Vierinen","doi":"10.5194/angeo-40-519-2022","DOIUrl":null,"url":null,"abstract":"Abstract. Earth's lower ionosphere is the region where terrestrial weather and space weather come together. Here, between 60 and 100 km altitude,\nsolar radiation governs the diurnal cycle of the ionized species. This altitude range is also the place where nanometre-sized dust particles,\nrecondensed from ablated meteoric material, exist and interact with free electrons and ions of the ionosphere. This study reports electron density\nmeasurements from the Arecibo incoherent-scatter radar being performed during sunset and sunrise conditions. An asymmetry of the electron density is\nobserved, with higher electron density during sunset than during sunrise. This asymmetry extends from solar zenith angles (SZAs) of 80 to\n100∘. This D-region asymmetry can be observed between 95 and 75 km altitude. The electron density observations are compared to the\none-dimensional Sodankylä Ion and Neutral Chemistry (SIC) model and a variant of the Whole Atmosphere Community Climate Model incorporating a\nsubset SIC's ion chemistry (WACCM-D). Both models also show a D-region sunrise–sunset asymmetry. However, WACCM-D compares slightly better to the\nobservations than SIC, especially during sunset, when the electron density gradually fades away. An investigation of the electron density continuity\nequation reveals a higher electron–ion recombination rate than the fading ionization rate during sunset. The recombination reactions are not fast\nenough to closely match the fading ionization rate during sunset, resulting in excess electron density. At lower altitudes electron attachment to\nneutrals and their detachment from negative ions play a significant role in the asymmetry as well. A comparison of a specific SIC version\nincorporating meteoric smoke particles (MSPs) to the observations revealed no sudden changes in electron density as predicted by the model. However,\nthe expected electron density jump (drop) during sunrise (sunset) occurs at 100∘ SZA when the radar signal is close to the noise floor,\nmaking a clear falsification of MSPs' influence on the D region impossible.\n","PeriodicalId":50777,"journal":{"name":"Annales Geophysicae","volume":null,"pages":null},"PeriodicalIF":1.7000,"publicationDate":"2022-08-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Annales Geophysicae","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.5194/angeo-40-519-2022","RegionNum":4,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"ASTRONOMY & ASTROPHYSICS","Score":null,"Total":0}
引用次数: 3
Abstract
Abstract. Earth's lower ionosphere is the region where terrestrial weather and space weather come together. Here, between 60 and 100 km altitude,
solar radiation governs the diurnal cycle of the ionized species. This altitude range is also the place where nanometre-sized dust particles,
recondensed from ablated meteoric material, exist and interact with free electrons and ions of the ionosphere. This study reports electron density
measurements from the Arecibo incoherent-scatter radar being performed during sunset and sunrise conditions. An asymmetry of the electron density is
observed, with higher electron density during sunset than during sunrise. This asymmetry extends from solar zenith angles (SZAs) of 80 to
100∘. This D-region asymmetry can be observed between 95 and 75 km altitude. The electron density observations are compared to the
one-dimensional Sodankylä Ion and Neutral Chemistry (SIC) model and a variant of the Whole Atmosphere Community Climate Model incorporating a
subset SIC's ion chemistry (WACCM-D). Both models also show a D-region sunrise–sunset asymmetry. However, WACCM-D compares slightly better to the
observations than SIC, especially during sunset, when the electron density gradually fades away. An investigation of the electron density continuity
equation reveals a higher electron–ion recombination rate than the fading ionization rate during sunset. The recombination reactions are not fast
enough to closely match the fading ionization rate during sunset, resulting in excess electron density. At lower altitudes electron attachment to
neutrals and their detachment from negative ions play a significant role in the asymmetry as well. A comparison of a specific SIC version
incorporating meteoric smoke particles (MSPs) to the observations revealed no sudden changes in electron density as predicted by the model. However,
the expected electron density jump (drop) during sunrise (sunset) occurs at 100∘ SZA when the radar signal is close to the noise floor,
making a clear falsification of MSPs' influence on the D region impossible.
期刊介绍:
Annales Geophysicae (ANGEO) is a not-for-profit international multi- and inter-disciplinary scientific open-access journal in the field of solar–terrestrial and planetary sciences. ANGEO publishes original articles and short communications (letters) on research of the Sun–Earth system, including the science of space weather, solar–terrestrial plasma physics, the Earth''s ionosphere and atmosphere, the magnetosphere, and the study of planets and planetary systems, the interaction between the different spheres of a planet, and the interaction across the planetary system. Topics range from space weathering, planetary magnetic field, and planetary interior and surface dynamics to the formation and evolution of planetary systems.
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