Effect of near-surface heterogeneities on the pore-water pressure distribution and slope stability

Nurly Gofar; Ega Nanda Pangestika; Yudi Harianto; Herdian Gumay; Alfrendo Satyanaga

doi:10.22441/sinergi.2024.2.012

Penulis

Nurly Gofar Department of Civil Engineering, Graduate Program, Universitas Bina Darma, Indonesia
Ega Nanda Pangestika Department of Civil Engineering, Graduate Program, Universitas Bina Darma, Indonesia
Yudi Harianto Geoteknik Pratama Civil Engineering Laboratory, Indonesia
Herdian Gumay Department of Civil Engineering, Faculty of Engineering, Universitas Hasanuddin,
Alfrendo Satyanaga Department of Civil and Environmental Engineering, Nazarbayev University, Kazakhstan

DOI:

https://doi.org/10.22441/sinergi.2024.2.012

Kata Kunci:

Heterogeneity, Pore-water pressure, Rainfall, Slope stability, Suction,

Abstrak

Seepage and slope stability are important problems analyzed in geotechnical engineering. Conventionally, the analysis is performed in conditions where the soil is intact. However, near-surface soil is subjected to various conditions that lead to heterogeneity, for example, the presence of cracks in clay, relics in weathered rock, and plant roots. The presence of cracks and other forms of heterogeneity on the near-surface layer increases the rainfall infiltration into the slope and changes the pore water pressure distribution accordingly. Water infiltration increases the pore water pressure, raises groundwater level, and decreases the matrix suction of unsaturated soils - which is a critical factor for the stability of slopes. This study aims to evaluate the effect of varying permeability of near-surface soil on the rainwater infiltration to slope and, subsequently, the safety factor. In this case, the near-surface soil is modeled as a layer with higher permeability. Numerical analysis performed in this study using SEEP/W and SLOPE/W indicated that considering this condition results in a higher safety factor of the slope because the higher permeability resulting from heterogeneity helps dissipate pore water pressure, which is critical in maintaining the slope stability during heavy rainfall.