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A simple code to make it simple create and modify gempy's surface points files.

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Screator

A simple code to make it simple to create and modify Gempy's surface points files.

Work presented at EGU 2024 - Vienna, Austria.

How to use:

1- Download or clone this repository;

2- Open your terminal and go to the program directory;

3- run python screator.py (in case you want to change to your own seismic or geologic section, you should input your image and the real scale in meters of your section and then run the *.py file);

4- delimit your surface;

5- save the name of your surface;

6- repeat the process until you reach your desired number of features.

Contact:

In case of doubts, don't hesitate to get in touch with [email protected]

Curriculum:

Victor Carreira - Lattes Curriculum

Website:

More of me

References:

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  2. Caldas, M. F., & Zalán, P. V. (2009). Reconstituição cinemática e tectono-sedimentação associada a domos salinos nas águas profundas da Bacia de Santos, Brasil. B. Geoci. Petrobras, 17(2), 227-247.

  3. Carreira, V., Ponte Neto, C., & Bijani, R. (2018). A comparison of machine learning processes for classification of rock units using well log data. In 80th EAGE Conference and Exhibition 2018 (Vol. 2018, pp. 1-5). European Association of Geoscientists & Engineers.

  4. Carreira, V. R. (2024). Reconstruction of lithofacies using a supervised Self-Organizing Map: Application in pseudo-wells based on a synthetic geologic cross-section. Artificial Intelligence in Geosciences, 5, 100072. DOI

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  6. Müller, R. D., Flament, N., Cannon, J., Tetley, M. G., Williams, S. E., Cao, X., Bodur, Ö. F., Zahirovic, S., & Merdith, A. (2022). A tectonic-rules-based mantle reference frame since 1 billion years ago – implications for supercontinent cycles and plate–mantle system evolution. Solid Earth, 13(7), 1127-1159. DOI

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  8. Ramirez, A. A., Kuchle, J., Alvarenga, R. D. S., Scherer, C., & Goldberg, K. (2015). Análise sismoestratigráfica da seção rifte da Bacia de Santos, Brasil. Pesquisas em Geociências, 42(3), 263. DOI

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2- Thorium normalisation for identification of organic carbon anomalies during the Lower Cretaceous paleolakes in the Southern Hemisphere.

  1. Barberes, G. A., Barata, M. T., Pena Dos Reis, R., & Spigolon, A. L. D. (2020). Hydrocarbon anomalies using airborne gamma radiation over the unconventional petroleum system of the South Portuguese Zone, Portugal. Applied Radiation and Isotopes, 166, 109406. DOI

  2. Bian, W., Yang, T., Jiang, Z., Jin, J., Gao, F., Wang, S., Peng, W., Zhang, S., Wu, H., Li, H., Cao, L., & Deng, C. (2020). Paleomagnetism of the Late Cretaceous Red Beds From the Far Western Lhasa Terrane: Inclination Discrepancy and Tectonic Implications. Tectonics, 39(8), e2020TC006280. DOI

  3. El-Khadragy, A. A., Shazly, T. F., AlAlfy, I. M., Ramadan, M., & El-Sawy, M. Z. (2018). Thorium normalization as a hydrocarbon accumulation indicator for Lower Miocene rocks in Ras Ghara area, Gulf of Suez, Egypt. NRIAG Journal of Astronomy and Geophysics, 7(1), 78-83. DOI

  4. Fertl, W. H. (1979). GAMMA RAY SPECTRAL DATA ASSISTS IN COMPLEX FORMATION EVALUATION.

  5. Kelts, K. (1988). Environments of deposition of lacustrine petroleum source rocks: an introduction. Geological Society, London, Special Publications, 40(1), 3-26.

  6. Lewis, D. S., Ensley, R., & Leander, M. (2014). New Insights into Late Synrift Subsidence from Detailed Well Ties and Seismic Mapping, Campos Basin, Brazil. In Sedimentary Basins: Origin, Depositional Histories, and Petroleum Systems. SEPM Society for Sedimentary Geology. DOI

  7. Lourenço, J., Menezes, P. T. L., & Barbosa, V. C. F. (2014). Connecting onshore-offshore Campos Basin structures: Interpretation of high-resolution airborne magnetic data. Interpretation, 2(4), SJ35-SJ45. DOI

  8. Merdith, A. S., Williams, S. E., Collins, A. S., Tetley, M. G., Mulder, J. A., Blades, M. L., Young, A., Armistead, S. E., Cannon, J., Zahirovic, S., & Müller, R. D. (2021). Extending full-plate tectonic models into deep time: Linking the Neoproterozoic and the Phanerozoic. Earth-Science Reviews, 214, 103477. DOI

  9. Mohriak, W. U., Nóbrega, M., Odegard, M. E., Gomes, B. S., & Dickson, W. G. (2010). Geological and geophysical interpretation of the Rio Grande Rise, south-eastern Brazilian margin: extensional tectonics and rifting of continental and oceanic crusts. Petroleum Geoscience, 16(3), 231-245. DOI

  10. Müller, R. D., Flament, N., Cannon, J., Tetley, M. G., Williams, S. E., Cao, X., Bodur, Ö. F., Zahirovic, S., & Merdith, A. (2022). A tectonic-rules-based mantle reference frame since 1 billion years ago – implications for supercontinent cycles and plate–mantle system evolution. Solid Earth, 13(7), 1127-1159. DOI

  11. Saunders, D. F., Burson, K. R., Branch, J. F., & Thompson, C. K. (1993). Relation of thorium‐normalized surface and aerial radiometric data to subsurface petroleum accumulations. GEOPHYSICS, 58(10), 1417-1427. DOI

  12. Saunders, D. F., Terry, S. A., & Thompson, C. K. (2012). Test of National Uranium Resource Evaluation gamma‐ray spectral data in petroleum reconnaissance. Geophysics. DOI

  13. Scotese, C. (2013). Kt globe, paleomap project, evanston. DOI

  14. Williams, G. E. (1993). History of the earth's obliquity. Earth-Science Reviews, 34(1), 1-45. DOI

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