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Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves. / Koval, Andrey V. ; Gavrilov, Nikolai M. ; Pogoreltsev, Аlexander I. ; Shevchuk, Nikita O. .

EGUsphere: EGU General Assembly, Wien 3-10 May 2020. Vol. EGU2020 Wien : European Geosciences Union, 2020. 2045.

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Koval, AV, Gavrilov, NM, Pogoreltsev, АI & Shevchuk, NO 2020, Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves. in EGUsphere: EGU General Assembly, Wien 3-10 May 2020. vol. EGU2020, 2045, European Geosciences Union, Wien, EGU General Assembly 2020, Vienna, Austria, 3/05/20. https://doi.org/10.5194/egusphere-egu2020-2045

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@inbook{0756b1b454bd4448ad3144e4813ca5bb,
title = "Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves",
abstract = "Atmospheric large-scale disturbances, for instance planetary waves, play a significant role in atmospheric general circulation, influencing its dynamical and thermal conditions. Solar activity may influence the mean temperature at altitudes above 100 km and alter conditions of wave propagation and reflection in the thermosphere. Using numerical simulations of the general atmospheric circulation during boreal winter, statistically confident evidences are obtained for the first time, demonstrating that changes in the solar activity (SA) in the thermosphere at heights above 100 km can influence propagation and reflection conditions for stationary planetary waves (SPWs) and can modify the middle atmosphere circulation below 100 km. A numerical mechanistic model simulating atmospheric circulation and SPWs at heights 0 – 300 km is used. To achieve sufficient statistical confidence, 80 pairs of 15-day intervals were extracted from an ensemble of 16 pairs of model runs corresponding to low and high SA. Results averaged over these intervals show that impacts of SA above 100 km change the mean zonal wind and temperature up to 10% at altitudes below 100 km. The statistically confident changes in SPW amplitudes due to SA impacts above 100 km reach up to 50% in the thermosphere and 10 – 15% in the middle atmosphere depending on zonal wavenumber. Changes in wave amplitudes correspond to variations of the EP-flux and may alter dynamical and thermal SPW impacts on the mean wind and temperature.",
keywords = "thermosphere, Solar activity, circulation, MIDDLE ATMOSPHERE, modeling",
author = "Koval, {Andrey V.} and Gavrilov, {Nikolai M.} and Pogoreltsev, {Аlexander I.} and Shevchuk, {Nikita O.}",
note = "Koval, A. V., Gavrilov, N. M., Pogoreltsev, A. I., Shevchuk, N. O., Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves. Abstract, EGUsphere-EGU2020-2045, https://doi.org/10.5194/egusphere-egu2020-2045, 2020; null ; Conference date: 03-05-2020 Through 08-05-2020",
year = "2020",
month = may,
day = "4",
doi = "10.5194/egusphere-egu2020-2045",
language = "English",
volume = "EGU2020",
booktitle = "EGUsphere",
publisher = "European Geosciences Union",
address = "Germany",

}

RIS

TY - CHAP

T1 - Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves

AU - Koval, Andrey V.

AU - Gavrilov, Nikolai M.

AU - Pogoreltsev, Аlexander I.

AU - Shevchuk, Nikita O.

N1 - Koval, A. V., Gavrilov, N. M., Pogoreltsev, A. I., Shevchuk, N. O., Influence of thermospheric effects of solar activity on the middle atmosphere circulation and stationary planetary waves. Abstract, EGUsphere-EGU2020-2045, https://doi.org/10.5194/egusphere-egu2020-2045, 2020

PY - 2020/5/4

Y1 - 2020/5/4

N2 - Atmospheric large-scale disturbances, for instance planetary waves, play a significant role in atmospheric general circulation, influencing its dynamical and thermal conditions. Solar activity may influence the mean temperature at altitudes above 100 km and alter conditions of wave propagation and reflection in the thermosphere. Using numerical simulations of the general atmospheric circulation during boreal winter, statistically confident evidences are obtained for the first time, demonstrating that changes in the solar activity (SA) in the thermosphere at heights above 100 km can influence propagation and reflection conditions for stationary planetary waves (SPWs) and can modify the middle atmosphere circulation below 100 km. A numerical mechanistic model simulating atmospheric circulation and SPWs at heights 0 – 300 km is used. To achieve sufficient statistical confidence, 80 pairs of 15-day intervals were extracted from an ensemble of 16 pairs of model runs corresponding to low and high SA. Results averaged over these intervals show that impacts of SA above 100 km change the mean zonal wind and temperature up to 10% at altitudes below 100 km. The statistically confident changes in SPW amplitudes due to SA impacts above 100 km reach up to 50% in the thermosphere and 10 – 15% in the middle atmosphere depending on zonal wavenumber. Changes in wave amplitudes correspond to variations of the EP-flux and may alter dynamical and thermal SPW impacts on the mean wind and temperature.

AB - Atmospheric large-scale disturbances, for instance planetary waves, play a significant role in atmospheric general circulation, influencing its dynamical and thermal conditions. Solar activity may influence the mean temperature at altitudes above 100 km and alter conditions of wave propagation and reflection in the thermosphere. Using numerical simulations of the general atmospheric circulation during boreal winter, statistically confident evidences are obtained for the first time, demonstrating that changes in the solar activity (SA) in the thermosphere at heights above 100 km can influence propagation and reflection conditions for stationary planetary waves (SPWs) and can modify the middle atmosphere circulation below 100 km. A numerical mechanistic model simulating atmospheric circulation and SPWs at heights 0 – 300 km is used. To achieve sufficient statistical confidence, 80 pairs of 15-day intervals were extracted from an ensemble of 16 pairs of model runs corresponding to low and high SA. Results averaged over these intervals show that impacts of SA above 100 km change the mean zonal wind and temperature up to 10% at altitudes below 100 km. The statistically confident changes in SPW amplitudes due to SA impacts above 100 km reach up to 50% in the thermosphere and 10 – 15% in the middle atmosphere depending on zonal wavenumber. Changes in wave amplitudes correspond to variations of the EP-flux and may alter dynamical and thermal SPW impacts on the mean wind and temperature.

KW - thermosphere

KW - Solar activity

KW - circulation

KW - MIDDLE ATMOSPHERE

KW - modeling

U2 - 10.5194/egusphere-egu2020-2045

DO - 10.5194/egusphere-egu2020-2045

M3 - Other chapter contribution

VL - EGU2020

BT - EGUsphere

PB - European Geosciences Union

CY - Wien

Y2 - 3 May 2020 through 8 May 2020

ER -

ID: 60337095