# The impact of energetic electron precipitation on mesospheric hydroxyl   during a year of solar minimum

**Authors:** Annet Eva Zawedde, Hilde Nesse Tyss{\o}y, Robert Hibbins, Patrick J., Espy, Linn-Kristine Glesnes {\O}degaard, Marit Irene Sandanger, and Johan, Stadsnes

arXiv: 1706.00323 · 2017-06-02

## TL;DR

This study investigates how energetic electron precipitation during a solar minimum influences mesospheric hydroxyl levels, revealing localized OH enhancements linked to geomagnetic activity and atmospheric dynamics.

## Contribution

It introduces a new analysis technique for estimating precipitating electron fluxes and assesses their impact on mesospheric hydroxyl during solar minimum.

## Key findings

- Localized OH enhancements over northern Russia linked to EEP.
- OH enhancements over North America likely caused by atmospheric dynamics.
- Substantial EEP-driven OH production occurs even during solar minimum.

## Abstract

In 2008 a sequence of geomagnetic storms occurred triggered by high-speed solar wind streams from coronal holes. Improved estimates of precipitating fluxes of energetic electrons are derived from measurements on board the NOAA/POES 18 satellite using a new analysis technique. These fluxes are used to quantify the direct impact of energetic electron precipitation (EEP) during solar minimum on middle atmospheric hydroxyl (OH) measured from the Aura satellite. During winter, localized longitudinal density enhancements in the OH are observed over northern Russia and North America at corrected geomagnetic latitudes poleward of 55$^{\circ}$. Although the northern Russia OH enhancement is closely associated with increased EEP at these longitudes, the strength and location of the North America enhancement appear to be unrelated to EEP. This OH density enhancement is likely due to vertical motion induced by atmospheric wave dynamics that transports air rich in atomic oxygen and atomic hydrogen downward into the middle atmosphere, where it plays a role in the formation of OH. In the Southern Hemisphere, localized enhancements of the OH density over West Antarctica can be explained by a combination of enhanced EEP due to the local minimum in Earth's magnetic field strength and atmospheric dynamics. Our findings suggest that even during solar minimum, there is substantial EEP-driven OH production. However, to quantify this effect, a detailed knowledge of where and when the precipitation occurs is required in the context of the background atmospheric dynamics.

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Source: https://tomesphere.com/paper/1706.00323