Monitoring near surface seismic attenuation variations using train tremors

Laura Pinzon-Rincon; Destin Nziengui Bâ; Aurélien Mordret; Olivier Coutant; Florent Brenguier

doi:10.1029/2024GL113935

Monitoring near surface seismic attenuation variations using train tremors

Laura Pinzon-Rincon, Destin Nziengui Bâ, Aurélien Mordret, Olivier Coutant, Florent Brenguier

Afdeling for Geofysik og Sedimentære Bassiner

Publikation: Bidrag til tidsskrift › Artikel › Forskning › peer review

2 Citationer (Scopus)

Resumé

Passive seismic methods hold valuable information about the physical properties of the subsurface, enabling continuous, non-intrusive monitoring of groundwater dynamics. This study introduces a novel methodology for monitoring near-surface seismic attenuation variations using repetitive seismic noise sources. Our approach employs a single-station technique to quantify seismic attenuation variations by evaluating the linear relationship between the frequency and spectrum amplitude variations. We applied this method in the Lyon water catchment area, utilizing train tremors as a continuous and stable seismic source. The case study demonstrates that seismic attenuation variations correlate strongly with environmental factors such as rainfall and significant changes in the water table due to a flood event. This methodology offers an effective and practical means to continuously monitor the subsurface seismic attenuation using opportune noise sources, providing valuable insights into groundwater dynamics and subsurface processes.

Originalsprog	Engelsk
Artikelnummer	e2024GL113935
Antal sider	12
Tidsskrift	Geophysical Research Letters
Vol/bind	52
Udgave nummer	11
DOI	https://doi.org/10.1029/2024GL113935
Status	Udgivet - 16 jun. 2025

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10.1029/2024GL113935Licens: CC BY-NC

Citationsformater

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AU - Pinzon-Rincon, Laura

AU - Nziengui Bâ, Destin

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AU - Coutant, Olivier

AU - Brenguier, Florent

PY - 2025/6/16

Y1 - 2025/6/16

N2 - Passive seismic methods hold valuable information about the physical properties of the subsurface, enabling continuous, non-intrusive monitoring of groundwater dynamics. This study introduces a novel methodology for monitoring near-surface seismic attenuation variations using repetitive seismic noise sources. Our approach employs a single-station technique to quantify seismic attenuation variations by evaluating the linear relationship between the frequency and spectrum amplitude variations. We applied this method in the Lyon water catchment area, utilizing train tremors as a continuous and stable seismic source. The case study demonstrates that seismic attenuation variations correlate strongly with environmental factors such as rainfall and significant changes in the water table due to a flood event. This methodology offers an effective and practical means to continuously monitor the subsurface seismic attenuation using opportune noise sources, providing valuable insights into groundwater dynamics and subsurface processes.

AB - Passive seismic methods hold valuable information about the physical properties of the subsurface, enabling continuous, non-intrusive monitoring of groundwater dynamics. This study introduces a novel methodology for monitoring near-surface seismic attenuation variations using repetitive seismic noise sources. Our approach employs a single-station technique to quantify seismic attenuation variations by evaluating the linear relationship between the frequency and spectrum amplitude variations. We applied this method in the Lyon water catchment area, utilizing train tremors as a continuous and stable seismic source. The case study demonstrates that seismic attenuation variations correlate strongly with environmental factors such as rainfall and significant changes in the water table due to a flood event. This methodology offers an effective and practical means to continuously monitor the subsurface seismic attenuation using opportune noise sources, providing valuable insights into groundwater dynamics and subsurface processes.

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Monitoring near surface seismic attenuation variations using train tremors

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