Infrasound signals are used to monitor various anthropogenic and natural sources. To determine precise source locations and energy, an accurate wind and temperature model from the surface up to the lower thermosphere is necessary, hence operational NWP products are of great importance for routine infrasound monitoring activities. However, many of these models focus on tropospheric conditions, and the middle and upper atmosphere, where the relevant infrasound waveguides for long-range propagation are found, is not well represented. UA-ICON is an upper-atmosphere version of the ICOsahedral Non-hydrostatic weather and climate model (ICON) that provides modeled atmospheric parameters up to the thermosphere. From an infrasound perspective, small-scale perturbations—most notably gravity waves—can have a large impact on propagation due to the effects on both the background winds and temperatures, hence on the acoustic waveguides, but also due to the small perturbations they produce, which cause partial reflections of acoustic waves. Therefore, the transient-3-D Multi-Scale Gravity Wave Model (MSGWaM) was used within UA-ICON to produce accurate background conditions and predict the global gravity wave activity. We will present the methodology used to generate the wind and temperature gravity wave perturbation profiles, and analysis of infrasound propagation using these gravity wave realizations.
Kristoffersen et al. (Tue,) studied this question.