Abstract
Energetic particle precipitation is one of the main processes by which the sun influences atmospheric composition and structure. The polar middle atmosphere is chemically disturbed by the precipitation-induced production of nitric oxides (NOx) and hydrogen oxides (HOx) and the associated ozone (O3) loss, but the importance for the dynamics is still debated. The role of precipitating medium energy electrons (MEEs), which are able to penetrate into the mesosphere, has received increased attention, but has only recently begun to be incorporated in chemistry-climate models. We use the NCAR Whole Atmosphere Community Climate Model (WACCM) to study the climate impact from MEE precipitation by performing two idealized ensemble experiments under pre-industrial conditions, with and without the MEE forcing, over the period of the solar cycle 23 (only full calendar years, 1997–2007). Each experiment includes 20 11-year ensemble members, total 220 years. Our results indicate a strong month-to-month variability in the dynamical response to MEE throughout the winter period. We find a strengthening of the polar vortex in the northern hemisphere during December, but the signal decays rapidly in the following months. The polar vortex strengthening is likely attributable to planetary wave reduction due to increased zonal symmetries in upper stratospheric ozone heating, initially triggered by MEE-induced NOx advected into the sunlit regions. We also find a similar early winter polar vortex strengthening in the southern hemisphere during June. Changes in mean meridional circulation accompany these anomalous wave forcings, leading to dynamically-induced vertical temperature dipoles at high latitudes. The associated weakening of the stratospheric mean meridional circulation results in an upper stratospheric polar ozone deficit in early winter. This polar cap ozone deficit is strongest in the southern hemisphere and contributes to a polar vortex weakening in late winter, in concert with increased planetary wave forcing. In both hemispheres, the stratospheric polar vortex signal seems to migrate downwards into the troposphere and to the surface.
Highlights
Deciphering the evolution of past climate and predicting future climate requires a detailed understanding of the role of relevant climate forcings
We note that the N(2D) isopleths are more aligned along geographical latitudes in northern hemisphere (NH) than southern hemisphere (SH), since the geomagnetic latitudes are more parallel with geographic latitudes in NH
The longitudinal asymmetries in N(2D) production are mirrored in the nitric oxides (NOx) anomalies between 80 and 90 km, where high NOx anomaly coincides with high N(2D) production
Summary
Deciphering the evolution of past climate and predicting future climate requires a detailed understanding of the role of relevant climate forcings. The solar forcing comprises two main components, namely electromagnetic radiation and energetic particle precipitation (EPP), each involving several mechanisms and pathways to influence the atmosphere (see Gray et al, 2010; Lockwood, 2012, for reviews). Variations in total solar irradiance have been linked to a “bottom-up” mechanism, initiated by changes in the sea surface temperature, cloudiness and convection (e.g., van Loon, 2012). Varia tions in spectral irradiance over the 11-year solar cycle are thought to initiate a top-down mechanism, starting with ozone and temperature changes in the mid and low-latitude upper stratosphere, followed by downward migration of zonal-mean zonal wind anomalies at high-latitudes (e.g., Kodera and Kuroda, 2002). The influence of EPP involves several pathways but its overall climate impact is heavily debated
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