Future Climate Change in the Thermosphere Under Varying Solar Activity Conditions

M. K. Brown*, H. G. Lewis, A. J. Kavanagh, I. Cnossen, S. Elvidge

*Corresponding author for this work

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Abstract

Increasing carbon dioxide concentrations in the mesosphere and lower thermosphere are increasing radiative cooling in the upper atmosphere, leading to thermospheric contraction and decreased neutral mass densities at fixed altitudes. Previous studies of the historic neutral density trend have shown a dependence upon solar activity, with larger F10.7 values resulting in lower neutral density reductions. To investigate the impact on the future thermosphere, the Whole Atmosphere Community Climate Model with ionosphere and thermosphere extension has been used to simulate the thermosphere under increasing carbon dioxide concentrations and varying solar activity conditions. These neutral density reductions have then been mapped onto the Shared Socioeconomic Pathways published by the Intergovernmental Panel on Climate Change. The neutral density reductions can also be used as a scaling factor, allowing commonly used empirical models to account for CO2 trends. Under the “best case” SSP1‐2.6 scenario, neutral densities reductions at 400 km altitude peak (when CO2 = 474 ppm) at a reduction of 13%–30% (under high and low solar activity respectively) compared to the year 2000. Higher CO2 concentrations lead to greater density reductions, with the largest modeled concentration of 890 ppm resulting in a 50%–77% reduction at 400 km, under high and low solar activity respectively.
Original languageEnglish
Article numbere2024JA032659
Number of pages10
JournalJournal of Geophysical Research: Space Physics
Volume129
Issue number9
Early online date28 Aug 2024
DOIs
Publication statusPublished - Sept 2024

Keywords

  • climate change
  • space environment
  • LEO
  • thermospheric modeling
  • thermosphere
  • atmospheric drag

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