GLOBAL JOURNAL OF EARTH AND ENVIRONMENTAL SCIENCE
Integrity Research Journals
ISSN: 2636-6002
Model: Open Access/Peer Reviewed
DOI: 10.31248/GJEES
Start Year: 2016
Email: gjees@integrityresjournals.org
Estimation of near-surface geotechnical parameters using seismic measurements at phase ǀǀ site, Ahmadu Bello University Zaria, North-western Nigeria
https://doi.org/10.31248/GJEES2019.052 | Article Number: 2D6CC43A1 | Vol.5 (1) - April 2020
Received Date: 30 October 2019 | Accepted Date: 12 December 2019 | Published Date: 30 April 2020
Authors: Kabiru Onotu Momoh* , Umar Ishaq Muhammad , Ahmed Usman and Audu Usman Ibrahim
Keywords: Geotechnical, near-surface, P- and S-waves, seismic refraction, velocities.
Determination of the dynamic geotechnical properties and seismic wave velocities serves as essential inputs for a foundation design cognizant of seismic site response and rock strength. This study evaluates competent zones for construction at Ahmadu Bello University Zaria, Phase II site. Four shallow seismic refraction profiles were carried out using the ABEM Terraloc Pro seismograph. Compressional (P) and shear (S) waves were acquired and the time-term technique, which is a combination of linear least squares and delay time analysis to invert the first arrivals for a velocity section and then to tomography section was adopted. These sections were correlated with a borehole report and a good matching was observed. The result shows that the area consists of three subsurface layers; an overburden with average thickness of about 10.5 m and P- and S-wave velocities (velocities) of about 550 m/s and 345 m/s respectively, the weathered basement with an average thickness of 12.5 m and velocities of 950 m/s and 550 m/s respectively, while the fresh basement was found at a depth of about 24 m with velocities of 1250 m/s and 680 m/s respectively. The Concentration Index, Material Index, Poisson’s Ratio, and Stress Ratio were calculated to be in the range of 4.869 to 6.128, -0.032 to 0.312, 0.172 to 0.258, and 0.267 to 0.346 respectively in the study area. The seismic velocity values, engineering consolidation, and strength parameters showed that the subsurface soil/rock at the eastern parts of the study area is characterized by less competent soil/rock quality while the western parts are characterized by more competent soil/rock quality. Hence, the western and north-western parts are more preferable for the foundation of structures to be erected.
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