Evaluating the applicability of a screen diffraction approximation to local volcano infrasound

IF 2.5 Q2 Earth and Planetary Sciences

Volcanica Pub Date : 2021-05-07 DOI:10.30909/VOL.04.01.6785

S. Maher, R. Matoza, C. de Groot-Hedlin, Keehoon Kim, K. Gee

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引用次数: 13

Abstract

Atmospheric acoustic waves from volcanoes at infrasonic frequencies (0.01–20 Hz) can be used to estimate source parameters for hazard modeling, but signals are often distorted by wavefield interactions with topography, even at local recording distances (<15 km). We present new developments toward a simple empirical approach to estimate attenuation by topographic diffraction at reduced computational cost. We investigate the applicability of a thin screen diffraction relationship developed by Maekawa [1968, doi: https://doi.org/10.1016/0003-682X(68)90020- 0]. We use a 2D axisymmetric finite-difference method to show that this relationship accurately predicts power losses for infrasound diffraction over an idealized kilometer-scale screen; thus validating the scaling to infrasonic wavelengths. However, the Maekawa relationship overestimates attenuation for realistic volcano topography (using Sakurajima Volcano as an example). The attenuating effect of diffraction may be counteracted by constructive interference of multiple reflections along concave volcano slopes. We conclude that the Maekawa relationship is insufficient as formulated for volcano infrasound, and suggest modifications that may improve the prediction capability.

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评价筛衍射近似法对局部火山次声的适用性

来自火山的次声频率（0.01–20 Hz）的大气声波可用于估计危险建模的源参数，但信号通常会因波场与地形的相互作用而失真，即使在局部记录距离（<15 km）也是如此。我们提出了一种简单的经验方法，以降低计算成本来估计地形衍射的衰减。我们研究了由Maekawa[1968，doi:https://doi.org/10.1016/0003-682X（68）90020-0]。我们使用二维轴对称有限差分方法来表明，这种关系准确地预测了理想千米尺度屏幕上次声衍射的功率损耗；从而验证了到次声波长的缩放。然而，前川关系高估了真实火山地形的衰减（以樱岛火山为例）。衍射的衰减效应可以通过沿凹形火山斜坡的多次反射的相长干涉来抵消。我们得出的结论是，前川关系式不足以满足火山次声的要求，并提出了可能提高预测能力的修改建议。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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