AccScience Publishing / JSE / Online First / DOI: 10.36922/JSE025240016
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An innovative method for computing static corrections using seismic reflection horizons analysis

Youcef LADJADJ1,2* Mohamed Cherif BERGUIG1 Said GACI3
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1 Laboratory of Geophysics, Department of Geophysics, Faculty of Earth Sciences, Geography and Regional Planning, University of Sciences and Technology Houari Boumediene, Algiers, Algeria
2 Department of Physics, Faculty of Sciences, Ferhat Abbas University, Sétif, Algeria
3 Central Directorate Research and Development, Sonatrach, Boumerdès, Algeria
JSE 2025, 34(2), 025240016 https://doi.org/10.36922/JSE025240016
Submitted: 13 June 2025 | Revised: 4 August 2025 | Accepted: 5 August 2025 | Published: 26 August 2025
© 2025 by the Author(s). This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution 4.0 International License ( https://creativecommons.org/licenses/by/4.0/ )
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Abstract

Seismic exploration faces significant challenges due to the physical parameters and geometric complexity of near-surface layers, making their modeling essential for accurately calculating static corrections. These corrections are crucial for preserving the image of geological structures represented by seismic reflectors. However, obtaining key physical parameters, such as the replacement velocity of the substrate and the velocities and thicknesses of near-surface layers, remains challenging. This study proposes a novel approach that addresses the issue in an alternative way. The innovative calculation method allows the direct computation of static corrections, relying solely on the structural analysis of seismic horizons in the near-trace section. Notably, this approach does not require prior knowledge of the weathered zone model. The application of this method to both simulated and real reflection seismic data demonstrates its potential and effectiveness. The static corrections derived from this approach significantly improve seismic image quality and eliminate abnormal regional static corrections compared to calibrated refraction static corrections. Furthermore, this method does not require calibration with borehole data, simplifying the process and representing a significant advantage over traditional methods. In summary, this innovative approach provides an effective solution to the challenges of near-surface layer modeling, delivering substantial improvements quantitatively—through time and effort savings, and reduced error—and qualitatively by enhancing data quality, ensuring consistency with geological realities, and enabling more reliable geological interpretations.

Keywords
Static corrections
Weathered zone model
Near-surface layers
Near-surface structures
Near-trace section
Seismic horizons
Frequency decomposition
Funding
None.
Conflict of interest
The authors declare they have no competing interests.
References
[1]
  1. Cox M. Static Corrections for Seismic Reflection Surveys. Thousand Oaks: SEG Books; 1999. doi: 10.1190/1.9781560801818

 

  1. Marsden D. Static corrections: A review. Part I. Geophys Lead Edge. 1993a;12(1):43-49. doi: 10.1190/1.1436912

 

  1. Marsden D. Static corrections: A review. Part II. Lead Edge. 1993b;12(2):115-120. doi: 10.1190/1.1436936

 

  1. Yilmaz Ö, Stephen MD. Seismic Data Analysis: Processing, Inversion, and Interpretation of Seismic Data. Vol. I. Thousand Oaks: SEG Books; 2001.

 

  1. Gaci S. The use of wavelet-based denoising techniques to enhance the first-arrival picking on seismic traces. IEEE Trans Geosci Remote Sens. 2013;52(8):4558-4563. doi: 10.1109/TGRS.2013.2282422

 

  1. Lei J, Fang H, Zhu Y, et al. GPR detection localization of underground structures based on deep learning and reverse time migration. NDT E Int. 2024;143:103043. doi: 10.1016/j.ndteint.2024.103043

 

  1. Li J, Hu Z, Cui J, Lin G. Efficient GPU-accelerated seismic analysis strategy and scenario simulation for large-scale nuclear structure cluster-soil interaction over ten million DOFs. Comput Geotech. 2024;174:106583. doi: 10.1016/j.compgeo.2024.106583

 

  1. Zhou G, Jia G, Zhou X, et al. Adaptive high-speed echo data acquisition method for bathymetric LiDAR. IEEE Trans Geosci Remote Sens. 2024;62:1-17. doi: 10.1109/tgrs.2024.3386687

 

  1. Zhou G, Song N, Jia G, et al. Adaptive adjustment for laser energy and PMT gain through self-feedback of echo data in bathymetric LiDAR. IEEE Trans Geosci Remote Sens. 2024;62:1-22. doi: 10.1109/TGRS.2024.3403895

 

  1. Tlalka S, Sobocinski R. Modelling for Statics Correction. In: 75th EAGE Conference and Exhibition, London, UK; 2013. p. 10-13.

 

  1. Tlalka S. Static Corrections in Challenging Cases. India: Society of Petroleum Geophysicists; 2010.

 

  1. Boschetti F, Dentith MD, List RD. A fractal-based algorithm for detecting first arrivals on seismic traces. Geophysics. 1996;61:1095-1102. doi: 10.1190/1.1444030

 

  1. Coppens F. First arrival picking on common-offset trace collections for automatic estimation of static corrections. Geophys Prospect. 1985;33:1212-1231.doi: 10.1111/j.1365-2478.1985.tb01360.x

 

  1. Molyneux JB, Schmitt DR. First-break timing: Arrival onset times by direct correlation. Geophysics. 1999;64:1492-1501. doi: 10.1190/1.1444653

 

  1. Mousa WA, Al-Shuhail A, Al-Lehyani A. A new technique for first-arrival picking of refracted seismic data based on digital image segmentation. Geophysics. 2011;76:V79- V89. doi: 10.1190/geo2010-0322.1

 

  1. Zhang H, Thurber C, Rowen C. Automatic P-wave arrival detection and picking with multiscale wavelet analysis for single-component recordings. Bull Seismol Soc Am. 2003;93:1904-1912. doi: 10.1785/0120020241

 

  1. Alao JO, Lawal KM, Dewu BBM, Raimi J. Near-surface seismic refraction anomalies due to underground target models and the application in civil and environmental engineering. Phys Chem Earth. 2025;138:103845. doi: 10.1016/j.pce.2024.103845

 

  1. Gülünay N. The diminishing residual matrices method for surface-consistent statics: A review. Geophysics. 2017;82(4):V257-V274. doi: 10.1190/geo2016-0602.1

 

  1. Allen PA, Allen JR. Basin Analysis: Principles and Application to Petroleum Play Assessment. 3rd ed. United States: Wiley and Blackwell; 2013.

 

  1. Biddle KT, Christie-Blick N. Deformation and sedimentation in basins. In: Tectonics and Sedimentation. Tulsa: Society of Economic Paleontologists and Mineralogists; 1985.

 

  1. Gaci S, Hachay O, Nicolis O. Methods and Applications in Petroleum and Mineral Exploration and Engineering Geology. USA: Elsevier Editions; 2021. p. 410.

 

  1. Gaci S, Hachay O. Oil and Gas Exploration: Methods and Application. American Geophysical Union. USA: Wiley Editions; 2017. p. 296.

 

  1. Gaci S, Hachay O. Advances in Data, Methods, Models and Their Applications in Oil/Gas Exploration. Broadway: Publishing Group Editions; 2014. p. 382.

 

  1. Ladjadj Y. Structural Study of the Lower Chellif Basin Based on Gravimetric, Magnetic, and Seismic Data. (Thesis Title Translated from French). Master’s Thesis. Ferhat Abbas University-Sétif 1; 2018. Available from: https://dspace. univ-setif.dz:8888/jspui/handle/123456789/2448 [Last accessed on 2025 Aug 20].

 

  1. Sclater JG, Christie PAF. Continental stretching: An explanation of the post-mid-cretaceous subsidence of the central North Sea Basin. J Geophys Res. 1980;85(B7):3711-3739.

 

  1. Ziegler PA. Geodynamic evolution of the north sea rift and its influence on the development of the North Sea Basin. In: The North Sea: A Geoscientific Perspective. London: The Geological Society; 1990.

 

  1. Robinson EA, Treitel S. Principles of digital filtering. Geophysics. 1964;29:395-404.

 

  1. Buttkus B. Spectral Analysis and Filter Theory in Applied Geophysics. Berlin, Heidelberg: Springer; 2000. doi: 10.1007/978-3-642-57016-2

 

  1. Oppenheim AV, Schafer RW. Discrete-Time Signal Processing. 3rd ed. United Kingdom: Pearson; 2013.

 

  1. Dong X, Yang D. Crustal flow-induced earthquake revealed by full-waveform tomography and implications for prehistoric civilization destruction. J Geophys Res Solid Earth. 2025;130(4). doi: 10.1029/2024JB029745

 

  1. Fu L, Guo J, Shen W, et al. Geophysical evidence of the collisional suture zone in the Prydz Bay, East Antarctica. Geophys Res Lett. 2024;51(2):e2023GL106229. doi: 10.1029/2023GL106229

 

  1. Zhang H, Bao X, Zhao H. High-precision deblending of 3-D simultaneous source data based on prior information constraint. IEEE Geosci Remote Sens Lett. 2025;22:1. doi: 10.1109/LGRS.2025.3526972

 

  1. Zhou G, Xu C, Zhang H, et al. PMT gain self-adjustment system for high-accuracy echo signal detection. Int J Remote Sens. 2022;43(19-24):7213-7235. doi: 10.1080/01431161.2022.2155089

 

  1. Zhai Z, Shu Q, Chen H, Liu Y. CCQC-based multi-seismic level optimum design of supplemental dampers in steel moment resisting frame. J Build Eng. 2025;108:112922. doi: 10.1016/j.jobe.2025.112922

 

  1. Zhang C, Zhu Z, Dai L, Wang S, Shi C. The incompatible deformation mechanism of underground tunnels crossing fault conditions in the southwest edge strong seismic zone of the Qinghai-Tibet Plateau: A study of shaking table test. Soil Dyn Earthq Eng. 2025;197:109482. doi: 10.1016/j.soildyn.2025.109482

 

  1. Liang S, Suping P, Dengke H. A novel static correction approach for eliminating the effect of geophones - a case study in coal reservoirs, Ordos Basin, China. Energies. 2018;11:3240. doi: 10.3390/en11123240
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Journal of Seismic Exploration, Print ISSN: 0963-0651, Published by AccScience Publishing
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