| Autor: |
Meyomesse, Samuel Erick, Koah Na Lebogo, Serge Parfait, Bisso, Dieudonné, Zo′o Zame, Philemon |
| Zdroj: |
SN Applied Sciences; Dec2023, Vol. 5 Issue 12, p1-13, 13p |
| Abstrakt: |
Road failure catastrophes have increased in frequency in the West Cameroon area. The collapsed soil characteristics that contribute to these phenomena in Bafoussam have been investigated using the geophysical investigation combined with geotechnical tests. The result of electrical resistivity tomography shows water conditions and heterogeneity of road foundation materials: resistivity values higher than 200 Ωm indicate dry materials, values between 30 and 200 Ωm define wet materials, and values lower than 30 Ωm indicate the very wet or water-saturated materials. These water-saturated materials can therefore move, bounded by a sliding surface of high-resistivity materials. Geotechnical properties analysis shows that these materials are clayey-sensitive water (64% clay fraction; A-7-6), very plastic (liquid limit: 46–63% plasticity limit: 29–39%), compressible, with high porosity (e > 0.8), low shear strength, and high friction angle (24–37°). The quality of foundation materials associated with high slopes (> 40°) and heavy rainfall in wet seasons (July–October) means that seepage water is the main factor responsible for the mass movement observed on the road of Western Cameroon. The construction or rehabilitation of these roads should be carried out in compliance with the natural conditions of the project site. Article highlights: - 2D Electrical Resistivity Tomography method is able to determine the nature, subsurface structure and water conditions of road foundation soils. - Geotechnical test can be used to define the physical and mechanical properties of road foundation soils. - These two techniques complement each other to understand the mass movement observed on two sections of road failures caused by seepage water. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
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