Seismic physics-based characterization of permafrost sites using surface waves

Liu, Hongwei; Maghoul, Pooneh; Shalaby, Ahmed

doi:10.5194/tc-16-1157-2022

Cited by 10 publications

(2 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Ice wedges form when water seeps into cracks in the ground during summer and then freezes during winter. The distribution of ice formations and ice content within the permafrost layer is highly variable (Liu et al, 2021). Previous studies confirm that the ice manuscript submitted to JGR: Earth Surface content in the permafrost around Barrow is very high in the upper part and decreases with depth (Brown et al, 1980).…”

Section: Global Warming Impacts On Permafrost Degradation and Ground ...mentioning

confidence: 92%

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Tourei,

Ji,

Rocha dos Santos

et al. 2024

Preprint

View full text Add to dashboard Cite

Subsurface processes are a driving factor behind some surface processes in permafrost regions, but multiple geophysical techniques are needed to reliably constrain the strength, water saturation, and ice content of permafrost across these heterogeneous regions. This research investigates the spatial variability of permafrost in undisturbed tundra and the permafrost degradation in disturbed tundra in Utqiaġvik, Alaska, using multiple geophysical techniques. Here, we integrate multichannel analysis of surface waves (MASW), electrical resistivity tomography (ERT), and ground temperature sensing to examine heterogeneity in permafrost’s geophysical characteristics. Using MASW, we find that the active layer's shear wave velocity, Vs, ranges from 240 to 370 m/s, and the permafrost's Vs ranges from 450 to 1700 m/s. These Vs profiles reveal cryostructures such as cryopeg and ice-rich zones in the permafrost layer. Additionally, we find an inverse relationship between in-situ Vs and ground temperature measurements. The integrated results of MASW and ERT provide valuable information for verifying ERT results for characterizing permafrost heterogeneity and cryostructure. This combination of geophysical and temperature sensing methods provides a new, robust approach to assess the spatial variability of permafrost in a coastal environment. Our results also indicate that civil infrastructure systems such as gravel roads and pile foundations affect permafrost by thickening the active layer, lowering the Vs, and reducing heterogeneity. Then, we show how the resulting Vs profiles can be used to estimate key parameters for designing buildings in permafrost regions and maintaining existing infrastructure in polar regions.

show abstract

Section: Global Warming Impacts On Permafrost Degradation and Ground ...mentioning

confidence: 92%

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Tourei,

Ji,

Rocha dos Santos

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…Ice wedges form when water seeps into cracks in the ground during summer and then freezes during winter. The distribution of ice formations and ice content within the permafrost layer is highly variable (Liu et al., 2021). Previous studies confirm that the ice content in the permafrost around Barrow is very high in the upper part and decreases with depth (Brown et al., 1980).…”

Section: Introductionmentioning

confidence: 99%

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Tourei,

Ji,

Rocha dos Santos

et al. 2024

JGR Earth Surface

View full text Add to dashboard Cite

Subsurface processes significantly influence surface dynamics in permafrost regions, necessitating utilizing diverse geophysical methods to reliably constrain permafrost characteristics. This research uses multiple geophysical techniques to explore the spatial variability of permafrost in undisturbed tundra and its degradation in disturbed tundra in Utqiaġvik, Alaska. Here, we integrate multiple quantitative techniques, including multichannel analysis of surface waves (MASW), electrical resistivity tomography (ERT), and ground temperature sensing, to study heterogeneity in permafrost’s geophysical characteristics. MASW results reveal active layer shear wave velocities (Vs) between 240 and 370 m/s, and permafrost Vs between 450 and 1,700 m/s, typically showing a low‐high‐low velocity pattern. Additionally, we find an inverse relationship between in situ Vs and ground temperature measurements. The Vs profiles along with electrical resistivity profiles reveal cryostructures such as cryopeg and ice‐rich zones in the permafrost layer. The integrated results of MASW and ERT provide valuable information for characterizing permafrost heterogeneity and cryostructure. Corroboration of these geophysical observations with permafrost core samples’ stratigraphies and salinity measurements further validates these findings. This combination of geophysical and temperature sensing methods along with permafrost core sampling confirms a robust approach for assessing permafrost’s spatial variability in coastal environments. Our results also indicate that civil infrastructure systems such as gravel roads and pile foundations affect permafrost by thickening the active layer, lowering the Vs, and reducing heterogeneity. We show how the resulting Vs profiles can be used to estimate key parameters for designing buildings in permafrost regions and maintaining existing infrastructure in polar regions.

show abstract

A deep learning approach to satellite image time series coregistration through alignment of road networks

Pérez,

Maghoul,

Ashraf

2023

Neural Comput & Applic

View full text Add to dashboard Cite

Seismic physics-based characterization of permafrost sites using surface waves

Cited by 10 publications

References 48 publications

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

A deep learning approach to satellite image time series coregistration through alignment of road networks

Contact Info

Product

Resources

About