Energy transport in the thermosphere during the solar storms of April 2002

M.G. Mlynczak; Javier Martin-Torres; Geoff Crowley; David P. Kratz; Bernd Funke; Gang Lu; Manuel López-Puertas; James M. Russell III; Janet Kozyra; Chris Mertens; Ramesh Sharma; Larry Gordley; Richard Picard; Jeremy Winick; Larry Paxton

doi:10.1029/2005JA011141

Energy transport in the thermosphere during the solar storms of April 2002

M.G. Mlynczak, Javier Martin-Torres, Geoff Crowley, David P. Kratz, Bernd Funke, Gang Lu, Manuel López-Puertas, James M. Russell III, Janet Kozyra, Chris Mertens, Ramesh Sharma, Larry Gordley, Richard Picard, Jeremy Winick, Larry Paxton

Geology and Geophysics

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107 Citations (Scopus)

Abstract

The dramatic solar storm events of April 2002 deposited a large amount of energy into the Earth's upper atmosphere, substantially altering the thermal structure, the chemical composition, the dynamics, and the radiative environment. We examine the flow of energy within the thermosphere during this storm period from the perspective of infrared radiation transport and heat conduction. Observations from the SABER instrument on the TIMED satellite are coupled with computations based on the ASPEN thermospheric general circulation model to assess the energy flow. The dominant radiative response is associated with dramatically enhanced infrared emission from nitric oxide at 5.3 μm from which a total of ∼7.7 × 1023 ergs of energy are radiated during the storm. Energy loss rates due to NO emission exceed 2200 Kelvin per day. In contrast, energy loss from carbon dioxide emission at 15 μm is only ∼2.3% that of nitric oxide. Atomic oxygen emission at 63 μm is essentially constant during the storm. Energy loss from molecular heat conduction may be as large as 3.8% of the NO emission. These results confirm the “natural thermostat” effect of nitric oxide emission as the primary mechanism by which storm energy is lost from the thermosphere below 210 km.

Original language	English
Journal	Journal of Geophysical Research - Space Physics
Volume	110
Issue number	A12
DOIs	https://doi.org/10.1029/2005JA011141
Publication status	Published - 2005

Keywords

Atmospheric Composition and Structure: Airglow and aurora
Atmospheric Composition and Structure: Thermosphere: composition and chemistry
Atmospheric Composition and Structure: Thermosphere: energy deposition (3369)
Atmospheric Processes: Radiative processes
Solar Physics
Astrophysics
and Astronomy: Coronal mass ejections (2101)
thermosphere
energy balance
thermostat effect
nitric oxide
solar variability
atmospheric radiation

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10.1029/2005JA011141

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Mlynczak, M. G., Martin-Torres, J., Crowley, G., Kratz, D. P., Funke, B., Lu, G., López-Puertas, M., III, J. M. R., Kozyra, J., Mertens, C., Sharma, R., Gordley, L., Picard, R., Winick, J., & Paxton, L. (2005). Energy transport in the thermosphere during the solar storms of April 2002. Journal of Geophysical Research - Space Physics, 110(A12). https://doi.org/10.1029/2005JA011141

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abstract = "The dramatic solar storm events of April 2002 deposited a large amount of energy into the Earth's upper atmosphere, substantially altering the thermal structure, the chemical composition, the dynamics, and the radiative environment. We examine the flow of energy within the thermosphere during this storm period from the perspective of infrared radiation transport and heat conduction. Observations from the SABER instrument on the TIMED satellite are coupled with computations based on the ASPEN thermospheric general circulation model to assess the energy flow. The dominant radiative response is associated with dramatically enhanced infrared emission from nitric oxide at 5.3 μm from which a total of ∼7.7 × 1023 ergs of energy are radiated during the storm. Energy loss rates due to NO emission exceed 2200 Kelvin per day. In contrast, energy loss from carbon dioxide emission at 15 μm is only ∼2.3% that of nitric oxide. Atomic oxygen emission at 63 μm is essentially constant during the storm. Energy loss from molecular heat conduction may be as large as 3.8% of the NO emission. These results confirm the “natural thermostat” effect of nitric oxide emission as the primary mechanism by which storm energy is lost from the thermosphere below 210 km.",

keywords = "Atmospheric Composition and Structure: Airglow and aurora, Atmospheric Composition and Structure: Thermosphere: composition and chemistry, Atmospheric Composition and Structure: Thermosphere: energy deposition (3369), Atmospheric Processes: Radiative processes, Solar Physics, Astrophysics, and Astronomy: Coronal mass ejections (2101), thermosphere, energy balance, thermostat effect, nitric oxide, solar variability, atmospheric radiation",

author = "M.G. Mlynczak and Javier Martin-Torres and Geoff Crowley and Kratz, {David P.} and Bernd Funke and Gang Lu and Manuel L{\'o}pez-Puertas and III, {James M. Russell} and Janet Kozyra and Chris Mertens and Ramesh Sharma and Larry Gordley and Richard Picard and Jeremy Winick and Larry Paxton",

year = "2005",

doi = "10.1029/2005JA011141",

language = "English",

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journal = "Journal of Geophysical Research - Space Physics",

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AU - Mlynczak, M.G.

AU - Martin-Torres, Javier

AU - Crowley, Geoff

AU - Kratz, David P.

AU - Funke, Bernd

AU - Lu, Gang

AU - López-Puertas, Manuel

AU - III, James M. Russell

AU - Kozyra, Janet

AU - Mertens, Chris

AU - Sharma, Ramesh

AU - Gordley, Larry

AU - Picard, Richard

AU - Winick, Jeremy

AU - Paxton, Larry

PY - 2005

Y1 - 2005

N2 - The dramatic solar storm events of April 2002 deposited a large amount of energy into the Earth's upper atmosphere, substantially altering the thermal structure, the chemical composition, the dynamics, and the radiative environment. We examine the flow of energy within the thermosphere during this storm period from the perspective of infrared radiation transport and heat conduction. Observations from the SABER instrument on the TIMED satellite are coupled with computations based on the ASPEN thermospheric general circulation model to assess the energy flow. The dominant radiative response is associated with dramatically enhanced infrared emission from nitric oxide at 5.3 μm from which a total of ∼7.7 × 1023 ergs of energy are radiated during the storm. Energy loss rates due to NO emission exceed 2200 Kelvin per day. In contrast, energy loss from carbon dioxide emission at 15 μm is only ∼2.3% that of nitric oxide. Atomic oxygen emission at 63 μm is essentially constant during the storm. Energy loss from molecular heat conduction may be as large as 3.8% of the NO emission. These results confirm the “natural thermostat” effect of nitric oxide emission as the primary mechanism by which storm energy is lost from the thermosphere below 210 km.

AB - The dramatic solar storm events of April 2002 deposited a large amount of energy into the Earth's upper atmosphere, substantially altering the thermal structure, the chemical composition, the dynamics, and the radiative environment. We examine the flow of energy within the thermosphere during this storm period from the perspective of infrared radiation transport and heat conduction. Observations from the SABER instrument on the TIMED satellite are coupled with computations based on the ASPEN thermospheric general circulation model to assess the energy flow. The dominant radiative response is associated with dramatically enhanced infrared emission from nitric oxide at 5.3 μm from which a total of ∼7.7 × 1023 ergs of energy are radiated during the storm. Energy loss rates due to NO emission exceed 2200 Kelvin per day. In contrast, energy loss from carbon dioxide emission at 15 μm is only ∼2.3% that of nitric oxide. Atomic oxygen emission at 63 μm is essentially constant during the storm. Energy loss from molecular heat conduction may be as large as 3.8% of the NO emission. These results confirm the “natural thermostat” effect of nitric oxide emission as the primary mechanism by which storm energy is lost from the thermosphere below 210 km.

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KW - Atmospheric Composition and Structure: Thermosphere: composition and chemistry

KW - Atmospheric Composition and Structure: Thermosphere: energy deposition (3369)

KW - Atmospheric Processes: Radiative processes

KW - Solar Physics

KW - Astrophysics

KW - and Astronomy: Coronal mass ejections (2101)

KW - thermosphere

KW - energy balance

KW - thermostat effect

KW - nitric oxide

KW - solar variability

KW - atmospheric radiation

U2 - 10.1029/2005JA011141

DO - 10.1029/2005JA011141

M3 - Article

SN - 2169-9380

VL - 110

JO - Journal of Geophysical Research - Space Physics

JF - Journal of Geophysical Research - Space Physics

IS - A12

ER -

Energy transport in the thermosphere during the solar storms of April 2002

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Keywords

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