Analysis of Ground Geophysical, Airborne TEM, and Geotechnical Data for Mapping Quick Clays in Sweden

“…Quick clay was identified above the coarse-grained layer during visual inspections of the core samples of boreholes BH1 to BH3 (Salas-Romero et al, 2016). Figure 6a-e show the seismic results for line 5-5b, their interpretation, the earlier P-wave refraction tomography and RMT (Wang et al, 2016), and ATEM resistivity results (Bastani et al, 2017). Figure 6b also includes the natural gamma radiation and magnetic susceptibility data from borehole BH3 (distance to the line 0.23 m; Salas-Romero et al, 2016) and the total sounding data from borehole 7062 (distance to the line 90.3 m; BGA, 2018).…”

“…The thin dashed white line indicates the depth above which the results are considered of higher confidence. (e) ATEM resistivity results (Bastani et al, 2017) superimposed on the interpreted seismic section.…”

“…The detailed objectives are (i) 3-D geological-geophysical modelling of the larger-scale subsurface structures overlying and existing within bedrock-like possible fracture zones, (ii) understanding the role of an identified coarse-grained layer and its spatial relationship with the bedrock surface that may improve the hazard assessment, (iii) hydrological modelling of the groundwater within the coarse-grained layer to better understand the development of quick clays in the study area, and (iv) investigating the riverbanks of the Göta River, its bed, and mass-movement deposits. Reflection seismic (both legacy and new sets of seismic profiles acquired within this study), P-wave refraction tomography (mainly from Wang et al, 2016, but for the new profiles performed in this study), and airborne transient electromagnetic (ATEM) and radio magnetotelluric (RMT) resistivity models (Bastani et al, 2017;Wang et al, 2016) are correlated with borehole data (Branschens Geotekniska Arkiv - BGA, 2018;Salas-Romero et al, 2016) for the identification of different types of clays, coarse-grained materials, and bedrock. Using the interpreted seismic sections together with total sounding (BGA, 2018) and high-resolution lidar data (©Lantmäteriet), elevation surfaces from the top of the bedrock and the top and bottom of the coarse-grained layer are modelled.…”

Subsurface characterization of a quick-clay vulnerable area using near-surface geophysics and hydrological modelling

“…Quick clay was identified above the coarse-grained layer during visual inspections of the core samples of boreholes BH1 to BH3 (Salas-Romero et al, 2016). Figure 6a-e show the seismic results for line 5-5b, their interpretation, the earlier P-wave refraction tomography and RMT (Wang et al, 2016), and ATEM resistivity results (Bastani et al, 2017). Figure 6b also includes the natural gamma radiation and magnetic susceptibility data from borehole BH3 (distance to the line 0.23 m; Salas-Romero et al, 2016) and the total sounding data from borehole 7062 (distance to the line 90.3 m; BGA, 2018).…”

“…The thin dashed white line indicates the depth above which the results are considered of higher confidence. (e) ATEM resistivity results (Bastani et al, 2017) superimposed on the interpreted seismic section.…”

“…The detailed objectives are (i) 3-D geological-geophysical modelling of the larger-scale subsurface structures overlying and existing within bedrock-like possible fracture zones, (ii) understanding the role of an identified coarse-grained layer and its spatial relationship with the bedrock surface that may improve the hazard assessment, (iii) hydrological modelling of the groundwater within the coarse-grained layer to better understand the development of quick clays in the study area, and (iv) investigating the riverbanks of the Göta River, its bed, and mass-movement deposits. Reflection seismic (both legacy and new sets of seismic profiles acquired within this study), P-wave refraction tomography (mainly from Wang et al, 2016, but for the new profiles performed in this study), and airborne transient electromagnetic (ATEM) and radio magnetotelluric (RMT) resistivity models (Bastani et al, 2017;Wang et al, 2016) are correlated with borehole data (Branschens Geotekniska Arkiv - BGA, 2018;Salas-Romero et al, 2016) for the identification of different types of clays, coarse-grained materials, and bedrock. Using the interpreted seismic sections together with total sounding (BGA, 2018) and high-resolution lidar data (©Lantmäteriet), elevation surfaces from the top of the bedrock and the top and bottom of the coarse-grained layer are modelled.…”

Subsurface characterization of a quick-clay vulnerable area using near-surface geophysics and hydrological modelling

Development of a Methodology for Quick Clay Mapping

Effects of Salinity and Curing Time on Compression Behavior of Fly Ash Stabilized Marine Clay