The present study determines the impact of chlorine ion chemistry on ozone loss in the middle atmosphere during very large solar proton events. This study involves solar particle events (SPEs) which can also induce geomagnetic disturbances in the earth’s magnetosphere leading to energetic electron precipitation (EEP) events. Solar coronal mass ejections can accelerate charged particles, primarily protons, to extremely high energy, resulting in Solar Particle Events (SPEs). Because of geomagnetic shielding, such energetic particles can precipitate into the Earth's atmosphere, particularly in polar regions. Ion-chemistry can cause SPE-induced chlorine activation, which depletes ozone in the polar middle atmosphere. To examine such events in the Northern Hemisphere (NH), we employ a cutting-edge 1D stacked-box model known as Exoplanetary Terrestrial Ion Chemistry (ExoTIC), which includes atmospheric ion and neutral composition. Measurement data from the Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) on ENVISAT were used to evaluate the model results using the Halloween SPE in late October 2003, a well-known large event, as a test field. Sensitivity tests were carried out for different model settings with a focus on the chlorine species of HOCl and ClONO2 as well as O3 and NOy. The model studies were carried out in the northern hemisphere for a high latitude of 67.5° N, inside the polar cap.
Ozone formation was observed after the event which is also
due to the impact of chlorine ion-chemistry. For the Halloween event with
temporal ionisation rates, ozone loss of 2.4 % during day-time and 10 % during
night-time was observed during the event that is due to chlorine ion-chemistry.
Ozone formation of 2-4 % was also found after the event both during day-time
and night-time. Comparison of the simulated effects against MIPAS observations
for the Halloween SPE revealed a rather good temporal and spatial agreement for
HOCl, ozone and NOy. For ClONO2, a good spatial agreement was found. The best
model setting was the one with full ion-chemistry where O(1D) was set to
photo-chemical equilibrium. HOCl and ozone changes are very well reproduced by
the model, specially for night-time. HOCl was found to be the main active
chlorine species under night-time conditions resulting in an increase of more
than 0.2 ppbv. Further, ClONO2 enhancements of 0.2-0.3 ppbv have been observed
both during daytime and night-time. In a nutshell, the most appropriate model
setting delivers satisfying result, i.e. the model can be considered to be
positively validated. As seen from the model simulations, both events were able
to perturb the polar stratosphere and mesosphere, with a high production of NOy
and HOx. Longer lasting and stronger stratospheric ozone loss was also seen for
the extreme event. Qualitative difference between the two events and a long
lasting impact on HOCl and HCl for the extreme event was found. Chlorine
ion-chemistry contributed to a stratospheric ozone loss of 2.4% during daytime
and 10% during night-time during the Halloween SPE as seen with time dependent
ionisation rates applied to the model. Furthermore, while comparing the two
events just for the event day, an ozone loss of 10% and 20% was found during
the Halloween SPE and the extreme event respectively which was due to the
impact of chlorine ion-chemistry.
Author(s) Details:
Monali Borthakur,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Miriam Sinnhuber,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Alexandra Laeng,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Thomas Reddmann,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Peter Braesicke,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Gabriele Stiller,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Thomas von Clarmann,
Institute of Meteorology and Climate research, Karlsruhe Institute of Technology, Karlsruhe, Germany.
Bernd Funke,
Instituto de Astrofísica de Andalucía, CSIC, Granada, Spain.
Ilya Usoskin,
University of Oulu, Oulu, Finland.
Jan Maik Wissing,
University of Rostock, Rostock, Germany.
Olesya Yakovchuk,
University of Rostock, Rostock, Germany.
Please see the link here: https://stm.bookpi.org/EIEGES-V7/article/view/13330
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