Lithological discrimination and mineralogical mapping using ASTER remote sensing data in the east-central Jebilet region, Morocco
Vol. 31 No. 2 (2025), Research papers
Vol. 31 No. 2 (2025)

Lithological discrimination and mineralogical mapping using ASTER remote sensing data in the east-central Jebilet region, Morocco

Research papers
https://doi.org/10.14746/logos.2025.31.2.13
Published 2025-09-09
Hayat El Khounaijri
Cadi Ayyad University image/svg+xml
Morocco
Ahmed Algouti
Cadi Ayyad University image/svg+xml
Morocco
Abdellah Algouti
Cadi Ayyad University image/svg+xml
Morocco
Mohamed Essemani
Cadi Ayyad University image/svg+xml
Morocco
Fatiha Hadach
Université Ibn Zohr image/svg+xml
Morocco
Soukaina Baid
Cadi Ayyad University image/svg+xml
Morocco
Salma Ezzahzi
Cadi Ayyad University image/svg+xml
Morocco
Salma Kabili
Cadi Ayyad University image/svg+xml
Morocco
Saloua Agli
Cadi Ayyad University image/svg+xml
Morocco
Naji Jdaba
Université Ibn Zohr image/svg+xml
Morocco
Journal cover Geologos, volume 31, no. 2, year 2025
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Keywords

GIS
ASTER
central Jebilet
lithological discrimination
mineralogical mapping

How to Cite

El Khounaijri, H., Algouti, A., Algouti, A., Essemani, M., Hadach, F., Baid, S., … Jdaba, N. (2025). Lithological discrimination and mineralogical mapping using ASTER remote sensing data in the east-central Jebilet region, Morocco. Geologos, 31(2), 167–177. https://doi.org/10.14746/logos.2025.31.2.13
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Abstract

This study evaluates the effectiveness of ASTER (Advanced Spaceborne Thermal Emission and Reflection Radiometer) satellite data for lithological discrimination and mineralogical mapping in the east-central Jebilet region, Morocco. ASTER data offer considerable potential for detecting spectral signatures of mineral zones and determining their composition. The main objective is to apply image processing techniques, such as band ratios (BR), principal component analysis (PCA) and minimum noise fraction (MNF), in order to identify and map characteristic minerals in the region. The application of various band ratios effectively mapped the distribution of key minerals and alteration zones in the study area. The band ratio (band7/band5) was used to identify kaolinite, while the ratio (band4+band6)/band5 highlighted the presence of a mineral group constisting of alunite, kaolinite and pyrophyllite. The ratio (band7+band9)/band8 revealed a set of a carbonate mineral, chlorite and epidote, whereas endoskarns composed of epidote, chlorite and amphibole were mapped using the ratio (band6+band9)/(band7+band8). The ratio (band5+band7)/band6 characterised phyllic alteration by detecting phyllosilicate minerals such as sericite, muscovite or illite. Phengite was mapped using the band5/band6 ratio. The distribution of these minerals was closely linked to the lithological variability of previously mapped geological units, highlighting the relevance and effectiveness of band ratios for geological mapping using remote sensing. The PCA and MNF components with the highest eigenvalues significantly improved lithological discrimination by reducing noise and refining the delineation of mineral zones. The results obtained have enabled the creation of a detailed map of mineral distribution, highlighting the alteration zones and lithological formations in the eastern Jebilet region of Morocco.time-consuming, yet inexpensive method that can be applied to other areas, especially those that are difficult to reach.

https://doi.org/10.14746/logos.2025.31.2.13
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Copyright (c) 2025 Hayat El Khounaijri, Ahmed Algouti, Abdellah Algouti, Mohamed Essemani, Fatiha Hadach, Soukaina Baid, Salma Ezzahzi, Salma Kabili, Saloua Agli, Naji Jdaba

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