Energy Transport in the Thermosphere During the Solar Storms of April 2002

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 t...

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Bibliographic Details
Main Authors: Mlynczak, Martin G, Martin-Torres, F J, Crowley, Geoff, Funke, Bernd, Lu, Gang, Russell, III, James M, Kozyra, Janet, Sharma, Ramesh, Gordley, Larry, Paxton, Larry
Format: Report
Language:English
Subjects:
Atmospheric Physics
CORONAL MASS EJECTIONS
ENERGY
ENERGY TRANSPORT
INFRARED RADIATION
NITRIC OXIDE
PE62601F
REPRINTS
SOLAR DISTURBANCES
SOLAR STORMS
THERMAL CONDUCTIVITY
THERMOSPHERE
TRANSPORT
WUAFRL2301BDA1
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Summary: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 microns from which a total of 7.7 x 10(to the 23rd power) 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 microns is only 2.3% that of nitric oxide. Atomic oxygen emission at 63 microns 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. Pub. in Journal of Geophysical Research, v110 nA12S25 p1-19, 2005. Prepared in collaboration with AS&M Inc., Hampton, VA; Southwest Research Institute, San Antonio, TX; Instituto de Astrofisica de Andalucia, Granada, Spain ;National Center for Atmospheric Research, Boulder, CO; Hampton University, Hampton, VA; University of Michigan, Ann Arbor, MI; G&A Technical Software, Newport News, VA; and Johns Hopkins Applied Physics Laboratory, Laurel, MD. Prepared in cooperation with Air Force Research Laboratory, Hanscom AFB, MA. Sponsored in part by NASA Langley Research Center. The original document contains color images.