Geophysical Investigation and 3D Modeling of Bedrock Morphology in an Urban Sediment-Filled Basin: The Case of Bolzano (Northern Italy)

Geophysical Investigation and 3D Modeling of Bedrock Morphology in an Urban Sediment-Filled Basin: The Case of Bolzano (Northern Italy)

Bedrock mapping is essential for understanding seismic amplification, particularly in sediment-filled valleys or basins. However, this can be hard in urban environments. We conducted a geophysical investigation of the sediment-filled Bolzano basin in Northern Italy, where three valleys converge. Thi...

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Bibliographic Details
Published in:Pure and applied geophysics Vol. 181; no. 6; pp. 1871 - 1893
Main Authors: Giulia, Sgattoni, Corrado, Morelli, Giovanni, Lattanzi, Silvia, Castellaro, Maurizio, Cucato, Werner, Chwatal, Volkmar, Mair
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-06-2024
Springer Nature B.V
Subjects:
Amplification
Amplitudes
Bedrock
Datasets
Depth
Earth and Environmental Science
Earth Sciences
Earthquakes
Geological history
Geology
Geophysical exploration
Geophysical methods
Geophysics/Geodesy
Geothermal exploration
Geothermal resources
Gravity data
Hydrogeological studies
Hydrogeology
Mapping
Modelling
Morphology
Resonance
Sediment
Sediments
Seismic activity
Seismic response
Seismic surveys
Spatial analysis
Stratigraphy
Urban areas
Urban environments
Valleys
Italy
Sedimentary basin
bedrock mapping
gravimetry
1D resonances
2D resonances
HVSR
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Summary:Bedrock mapping is essential for understanding seismic amplification, particularly in sediment-filled valleys or basins. However, this can be hard in urban environments. We conducted a geophysical investigation of the sediment-filled Bolzano basin in Northern Italy, where three valleys converge. This study uses low-impact, single-station geophysical methods suitable for urban areas to address the challenges of mapping in such environments. A dataset of 574 microtremor and gravity measurements, along with three seismic reflection lines, allows for the inference of the basin’s deep bedrock morphology, even without direct stratigraphic data. The dataset facilitates a detailed analysis of the spatial patterns of resonance frequencies and amplitudes, revealing 1D and 2D characteristics of the resonances. Notably, 2D resonances predominate along the Adige valley, i.e., the deepest part of the basin with depths up to 900 m. These 2D resonances, which cannot be interpreted through simple 1D frequency-depth relationships, are better understood by integrating gravity data to develop a depth model. The study identifies resonance frequencies ranging from 0.27 to over 3 Hz in Bolzano, affecting different building types during earthquakes. Maximum resonance amplitudes occur at lower frequencies, specifically at 2D resonance sites, therefore primarily impacting high structures. The 2D resonances are directional, with the most significant amplification occurring longitudinally along the valley axes. The resulting 3D bedrock model aids in seismic site response modeling, hydrogeological studies, and geothermal exploration and provides insights into the geological history of the basin, highlighting the role of the Adige Valley as a major drainage pathway.
ISSN:0033-4553
1420-9136
DOI:10.1007/s00024-024-03512-1