Understanding how mountain waves interact with an incoming acoustic wave.

What is it about?

The common approach to calculate infrasound propagation in the atmosphere consists in solving the acoustic equation in a given background atmospheric state. This approach captures the most significant ducts, but sometimes it fails in predicting important wavepackets that are related to small-scale atmospheric fluctuations. As in the troposphere these fluctuations are mainly produced by mountains, the contribution of these mountains to infrasound propagation remains an important open question.

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Why is it important?

The central result of this paper is that mountain wave dynamics may lead to strong attenuation or amplification of upcoming acoustic waves, regarding to the direct "mask" effect the mountain has on acoustic propagation. For a stable flow the mountain wave dynamics produces large horizontal winds and buoyancy disturbances at low level that result in intense downslope winds and Foehn. When the downslope wind is less intense, the flows can reinforce the acoustic waveguide over the mountain and lead to a signal of greater amplitude compared to that obtained by the "mask" effect. The acoustic waveguide is then strongly impacted which leads to a new kind of acoustic absorption.

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