Preprint Article Version 1 Preserved in Portico This version is not peer-reviewed

Seismic Signatures and Site Characterization of an Intermittent Stream in Dry and Flood Conditions: An Implication for Soil Losses and Landslide Triggering

Version 1 : Received: 27 September 2022 / Approved: 28 September 2022 / Online: 28 September 2022 (15:49:50 CEST)
Version 2 : Received: 15 November 2022 / Approved: 16 November 2022 / Online: 16 November 2022 (02:35:38 CET)

A peer-reviewed article of this Preprint also exists.

Hussain, Y.; Seivane, H.; Gao, Q.; Maciel, S.; Hamza, O.; Uagoda, R.; Borges, W. Seismic Signatures and Site Characterization of an Intermittent Stream in Dry and Flood Conditions: An Implication for Soil Losses and Landslide Triggering. Environmental Earth Sciences 2023, 82, doi:10.1007/s12665-023-10960-w. Hussain, Y.; Seivane, H.; Gao, Q.; Maciel, S.; Hamza, O.; Uagoda, R.; Borges, W. Seismic Signatures and Site Characterization of an Intermittent Stream in Dry and Flood Conditions: An Implication for Soil Losses and Landslide Triggering. Environmental Earth Sciences 2023, 82, doi:10.1007/s12665-023-10960-w.

Abstract

The seasonal soil losses and frequent shallow landslides in the Cerrado region of Brazil have high destructive potential with social, economic, and climatic implications. As fluvial systems substantially drive such environmental threats; therefore, it is essential to conduct geological site characterization and continuously monitor the seasonal erosive potentials of the rivers and streams. However, in such unstable and sensitive conditions, traditional intrusive investigation approaches may not be safe; therefore, the geophysical investigation might offer a good alternative. For the present study, a geophysical approach (particularly the seismic method) was adopted to examine the seismic footprints and GPR site characterization of a seasonal stream in the Rua do Matto, Brasilia, Brazil. The monitoring was conducted (at a safe distance) on the intermittent stream over several durations of dry (no rain) and rainy (flood) conditions. After pre-processing the raw data, the power spectral density (PSDs) was computed as a function of several variables (wind speed), time-frequency spectrograms, ambient noise displacement root mean square (RMS), the single station horizontal-to-vertical spectral ratio (HVSR) curves. In addition, change-point analysis was used for comparing the ambient noise with wind speed (both were well correlated). The GPR amplitude and waveform variation features were attributed to the subsurface material and the presence of boulders in the floodplain as well as regions (low coherence value) susceptible to erosion (weak spots). The river flows were evident on the mean probabilistic PSD values, spectrograms, HVSR curves and different patterns of RMS displacements (at selective ranges of frequency). The multi-peaks emerged on the HVSR curve are further analyzed for changes in amplitude, width and troughs possibly related to river activities and soil moisture due to rain. The approach provides the basis for non-destructive monitoring tools enabling the detection of 'seismic signatures' and weak spots of the fluvial channels for improving their environmental management.

Keywords

change-point analysis; weak spots; spectral analysis; ambient noise RMS; georadar attribute

Subject

Environmental and Earth Sciences, Geophysics and Geology

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