Electrical and seismic refraction methods: Fundamental concepts, current trends, and emerging machine learning prospects

Electrical and seismic refraction methods: Fundamental concepts, current trends, and emerging machine learning prospects

Abstract This comprehensive review examines electrical and seismic refraction methods, emphasizing their advanced applications in electrical resistivity tomography (ERT) and seismic refraction tomography (SRT). These techniques are crucial for understanding surface–subsurface crustal dynamics, offer...

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Bibliographic Details
Main Author: Adedibu Sunny Akingboye
Format: Article
Language:English
Published: Springer 2025-07-01
Series:Discover Geoscience
Subjects:
Electrical resistivity tomography (ERT)
Induced polarization (IP)
Self-potential (SP) method
Seismic refraction tomography (SRT)
Machine learning
Surface–subsurface modeling
Online Access:https://doi.org/10.1007/s44288-025-00169-8
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Summary:Abstract This comprehensive review examines electrical and seismic refraction methods, emphasizing their advanced applications in electrical resistivity tomography (ERT) and seismic refraction tomography (SRT). These techniques are crucial for understanding surface–subsurface crustal dynamics, offering critical insights into resistivity and velocity structures for geological and geohazard assessments. The review also explores the induced polarization (IP) and self-potential (SP) methods as complementary approaches. Despite their proven utility, electrical and seismic refraction approaches  face limitations arising from lithological heterogeneities, complex geological settings, and inherent data uncertainties. These challenges highlight the need for  multidisciplinary strategies, including methodological innovations and integrative data frameworks. Recently, machine learning (ML) techniques have been increasingly applied to these geophysical methods, particularly joint ERT and SRT analyses, optimizing nonlinear inversion processes and improving the interpretation of complex subsurface conditions. The case studies presented in this review evaluate how supervised and unsupervised ML techniques enhance ERT and SRT by improving data interpretation, refining inversion accuracy, automating lithological differentiation, and predicting seismic velocity from resistivity data. The findings emphasize the growing significance of integrating traditional geophysical methods with data-driven approaches to improve subsurface modeling. Continued innovations in ERT and SRT methodologies, along with emerging computational tools and ML applications, will further enhance their effectiveness in geological, hydrological, environmental, and hazard assessments.
ISSN:2948-1589

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