On the variability of the site-response parameters of the active rock slope in Brienz/Brinzauls (Switzerland)
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Date
2025-01
Publication Type
Journal Article, Journal Article
ETH Bibliography
yes
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Abstract
Unstable rock slopes, prone to collapse, pose an increasingly severe threat to both people and infrastructures, necessitating effective monitoring for risk mitigation. While many techniques rely on surface displacements to assess slope stability, seismic indicators such as resonance frequency, variations in seismic wave velocity and site amplification offer valuable insights into the structural integrity of the slope, aspects not captured by surface deformation alone. Research has demonstrated that these site-response parameters can serve as monitoring tools to detect precursory signs of failure, such as a drop in resonance frequency and relative seismic wave velocity prior to collapse. Still, environmental factors like temperature, precipitation, snow melt, earthquakes and freeze-thaw cycles transiently influence the seismic response. Our main objective is to understand the correlations and drivers between environmental parameters and seismic response, distinguishing between reversible and irreversible changes in dynamic behaviour. Over a 5-yr monitoring period, we continuously recorded ambient vibration data at the Brienz/Brinzauls instability and monitored three different site-response parameters (resonance frequency, site amplification, relative seismic wave velocity variation) using enhanced frequency domain decomposition, site-to-reference spectral ratio and single station ambient vibrations correlation techniques. Our results highlight a long-term increase in site amplification and a long-term decrease in first and second resonance frequencies, indicating ongoing structural weakening. Temperature was found to correlate with seasonal variations of seismic wave velocity with a few day’s time lag. Snow melting and rainfalls exerted a secondary influence, temporarily reducing relative seismic wave velocity during snowmelt and rainfall. Our findings suggest that single-station relative seismic velocity variations are mainly influenced by the shallow subsurface (depth of about 30 m), limiting its application to study the stability this deep structure.
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Publication status
published
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Journal / series
Volume
240 (1)
Pages / Article No.
779 - 790
Publisher
Oxford University Press
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Edition / version
Methods
Software
Geographic location
Date collected
Date created
Subject
Instability analysis; Seismic interferometry; Seismic noise; Site effects
Organisational unit
02818 - Schweiz. Erdbebendienst (SED) / Swiss Seismological Service (SED)
Notes
Funding
177586 - 4D seismic response and slope failure (SNF)
214916 - Quantification of the seismic response of instable slopes and its time variability: an important indicator for potential mass movements (SNF)
214916 - Quantification of the seismic response of instable slopes and its time variability: an important indicator for potential mass movements (SNF)
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