Your search keyword '"Ionosphere-atmosphere interactions"' showing total 5 results

1. Editorial: Coupling Processes in Terrestrial and Planetary Atmospheres

Author

Erdal Yiğit, Hermann Lühr, Alexander S. Medvedev, William Ward, Ana G. Elias, Jorge Luis Chau, Yoshizumi Miyoshi, Sonal Jain, and Libo Liu

Subjects

vertical coupling, gravity (buoyancy) waves, general circulation model (GCM), ionosphere–atmosphere interactions, thermosphere, ionosphere, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Published

2022

2. Large‐Scale Dune Aurora Event Investigation Combining Citizen Scientists' Photographs and Spacecraft Observations

Author

Maxime Grandin, Minna Palmroth, Graeme Whipps, Milla Kalliokoski, Mark Ferrier, Larry J. Paxton, Martin G. Mlynczak, Jukka Hilska, Knut Holmseth, Kjetil Vinorum, and Barry Whenman

Subjects

citizen science, dune aurora, ionosphere‐atmosphere interactions, mesospheric bore, Geology, QE1-996.5, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Recently, citizen scientist photographs led to the discovery of a new auroral form called “the dune aurora” which exhibits parallel stripes of brighter emission in the green diffuse aurora at about 100 km altitude. This discovery raised several questions, such as (i) whether the dunes are associated with particle precipitation, (ii) whether their structure arises from spatial inhomogeneities in the precipitating fluxes or in the underlying neutral atmosphere, and (iii) whether they are the auroral manifestation of an atmospheric wave called a mesospheric bore. This study investigates a large‐scale dune aurora event on 20 January 2016 above Northern Europe. The dunes were observed from Finland to Scotland, spanning over 1,500 km for at least 4 h. Spacecraft observations indicate that the dunes are associated with particle precipitation and reveal the presence of a temperature inversion layer below the mesopause during the event, creating suitable conditions for mesospheric bore formation. The analysis of a time lapse of pictures by a citizen scientist from Scotland leads to the estimate that, during this event, the dunes propagate toward the west‐southwest direction at about 200 m s−1, presumably indicating strong horizontal winds near the mesopause. These results show that citizen science and dune aurora studies can fill observational gaps and be powerful tools to investigate the least‐known region of near‐Earth space at altitudes near 100 km.

Published

2021

3. Investigation of ionospheric precursors related to deep and intermediate earthquakes based on spectral and statistical analysis.

Author

Oikonomou, Christina, Haralambous, Haris, and Muslim, Buldan

Subjects

*IONOSPHERIC storms, *TOTAL electron content (Atmosphere), *EARTHQUAKE damage, *GLOBAL Positioning System, *PLASMA bubbles

Abstract

Ionospheric TEC (Total Electron Content) variations prior to the deep (≈600 km) earthquake doublet close to magnetic equator in Peru ( M = 7.6) and to the intermediate (≈200 km) earthquake in Afghanistan ( M = 7.5) during 2015 were investigated using measurements from Global Navigation Satellite System (GNSS) network with the aim to detect possible ionospheric precursors of these events. For this we applied both statistical and spectral analysis. Ionospheric anomalies related to both earthquakes were observed few hours and few days prior to the earthquakes during daytime localized mainly near the epicenter. These were large-scale positive TEC anomalies and small-scale TEC oscillations with periods of 20 min and duration around 2–4 h appearing at the same local time each day. Several days prior to the earthquake in Peru a significant phenomenon was observed during afternoon time related to the modification of the Equatorial Ionization Anomaly (EIA) structure. During nighttime, however, it was not possible to identify any ionospheric earthquake precursor due to the concurrence of various phenomena, such as Equatorial Plasma Bubbles and pre- and post-midnight TEC peaks prior to Peru earthquake, and solar terminator transition prior to both earthquakes which could induce resembling ionospheric anomalies. [ABSTRACT FROM AUTHOR]

Published

2017

4. Large-scale dune aurora event investigation combining Citizen Scientists' photographs and spacecraft observations

Author

Martin G. Mlynczak, Milla Kalliokoski, Minna Palmroth, Mark Ferrier, Larry J. Paxton, Knut Holmseth, Maxime Grandin, Jukka Hilska, Graeme Whipps, Kjetil Vinorum, Barry Whenman, Particle Physics and Astrophysics, Space Physics Research Group, Department of Physics, and Doctoral Programme in Particle Physics and Universe Sciences

Subjects

INCIDENT ELECTRON-SPECTRA, dune aurora, 010504 meteorology & atmospheric sciences, Scale (ratio), Meteorology, Event (relativity), Optical measurements, 114 Physical sciences, 01 natural sciences, LAYERS, mesospheric bore, citizen science, 0103 physical sciences, Citizen science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Remote sensing, Spacecraft, business.industry, MAGNETIC-FIELD, General Medicine, STEVE, CORONAL MASS EJECTIONS, Solar wind, 13. Climate action, SOLAR-WIND, OPTICAL MEASUREMENTS, ionosphere-atmosphere interactions, DEDUCING COMPOSITION, BORE, Environmental science, MESOSPHERIC TEMPERATURE INVERSION, Scale (map), business, Geology

Abstract

Recently, citizen scientist photographs led to the discovery of a new auroral form called "the dune aurora" which exhibits parallel stripes of brighter emission in the green diffuse aurora at about 100 km altitude. This discovery raised several questions, such as (i) whether the dunes are associated with particle precipitation, (ii) whether their structure arises from spatial inhomogeneities in the precipitating fluxes or in the underlying neutral atmosphere, and (iii) whether they are the auroral manifestation of an atmospheric wave called a mesospheric bore. This study investigates a large-scale dune aurora event on 20 January 2016 above Northern Europe. The dunes were observed from Finland to Scotland, spanning over 1500 km for at least four hours. Spacecraft observations confirm that the dunes are associated with electron precipitation and reveal the presence of a temperature inversion layer below the mesopause during the event, creating suitable conditions for mesospheric bore formation. The analysis of a time lapse of pictures by a citizen scientist from Scotland leads to the estimate that, during this event, the dunes propagate toward the west-southwest direction at about 200 m/s, presumably indicating strong horizontal winds near the mesopause. These results show that citizen science and dune aurora studies can fill observational gaps and be powerful tools to investigate the least-known region of near-Earth space at altitudes near 100 km.

Published

2021

5. Sporadic Ca and Ca+ layers at mid-latitudes: Simultaneous observations and implications for their formation

Author

Gerding, M., Alpers, M., Höffner, J., and Von Zahn, U.

Subjects

mid-latitude ionosphere), Ionosphere (ion chemistry and composition, ionosphere-atmosphere interactions

Abstract

We report on the observations of 188 sporadic layers of either Ca atoms and/or Ca ions that we have observed during 112 nights of lidar soundings of Ca, and 58 nights of Ca+ soundings, at Kühlungsborn, Germany (54° N, 12° E). The Ca+ soundings have been performed simultaneously and in a common volume with the Ca soundings by two separate lidars. Correlations between sporadic neutral and ionized metal layers are demonstrated through four case studies. A systematic study of the variations of occurrence of sporadic Ca and Ca+ layers reveals that neutral and ionized Ca layers are not as closely correlated as expected earlier: (a) The altitude distribution shows the simultaneous occurrence of both sporadic Ca and Ca+ layers to be most likely only in the narrow altitude range between 90 and 95 km. Above that region, in the lower thermosphere, the sporadic ion layers are much more frequent than atom layers. Below 90 km only very few sporadic layers have been observed; (b) The seasonal variation of sporadic Ca layers exhibits a minimum of occurrence in summer, while sporadic Ca+ layers do not show a significant seasonal variation (only the dense Ca+ layers appear to have a maximum in summer). At mid-latitudes sporadic Ca layers are more frequent than sporadic layers of other atmospheric metals like Na or K. For the explanation of our observations new formation mechanisms are discussed.Key words. Ionosphere (ion chemistry and composition; ionosphere-atmosphere interactions; mid-latitude ionosphere)

Published

2018