Numerical Simulation of Seismoacoustic Wave Transformation at Sea–Land Interface

This study considers seismoacoustic wave propagation through the land–sea interface, i.e., in the presence of a coastal wedge, taking into account the real bottom bathymetry. It is of interest in the problems of coastal monitoring and environmental studies. An effective numerical model based on the...

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Veröffentlicht in:	Journal of marine science and engineering 2024-12, Vol.12 (12), p.2112
Hauptverfasser:	Dolgikh, Grigory, Bolsunovskii, Mikhail, Zharkov, Denis, Zhostkov, Ruslan, Presnov, Dmitriy, Razin, Andrey, Shurup, Andrey
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Sprache:	eng
Schlagworte:	Acoustics Analysis Asymptotic methods Bathymetry coastal wedge Environmental monitoring Environmental studies Exact solutions Experiments finite element Finite element method Lasers Mathematical analysis Mathematical models Numerical analysis numerical modeling Numerical models P-waves Parameter sensitivity Parameters Propagation Seismic waves seismoacoustics Seismology Sensitivity analysis Simulation methods Surface seismic waves surface waves T-phase Transmitters Water Wave propagation
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container_title	Journal of marine science and engineering
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creator	Dolgikh, Grigory Bolsunovskii, Mikhail Zharkov, Denis Zhostkov, Ruslan Presnov, Dmitriy Razin, Andrey Shurup, Andrey
description	This study considers seismoacoustic wave propagation through the land–sea interface, i.e., in the presence of a coastal wedge, taking into account the real bottom bathymetry. It is of interest in the problems of coastal monitoring and environmental studies. An effective numerical model based on the finite element method is proposed and implemented. An approximate analytical solution in the fluid and an asymptotic analytical solution for the surface seismic wave on the shore are considered to validate the numerical model. It is shown that in field experiment conditions the hydroacoustic signal generated by an underwater source with a power of ~200 W is transformed into a seismic wave on the shore with an amplitude of units of nanometers at distances of several kilometers, which can be measured by a sensitive sensor. An extensive series of numerical simulations with different model parameters was performed, which allowed us to evaluate the most appropriate propagation medium parameters to match the observed and calculated data.
doi_str_mv	10.3390/jmse12122112
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subjects	Acoustics Analysis Asymptotic methods Bathymetry coastal wedge Environmental monitoring Environmental studies Exact solutions Experiments finite element Finite element method Lasers Mathematical analysis Mathematical models Numerical analysis numerical modeling Numerical models P-waves Parameter sensitivity Parameters Propagation Seismic waves seismoacoustics Seismology Sensitivity analysis Simulation methods Surface seismic waves surface waves T-phase Transmitters Water Wave propagation
title	Numerical Simulation of Seismoacoustic Wave Transformation at Sea–Land Interface
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