Structural lineament mapping of Central-Eastern high atlas, Morocco, using ASAR/Envisat and SAR/sentinel 1B data

References

• Abdelouhed F, Ahmed A, Abdellah A, Mohammed I. 2021. Lineament mapping in the Ikniouen area (Eastern Anti-Atlas, Morocco) using Landsat-8 Oli and SRTM data. Remote Sens Appl Soc Environ. 23:100606.
   Google Scholar
• Abdullah, A., Akhir, J. M., & Abdullah, I. (2010). Automatic mapping of lineaments using shaded relief images derived from digital elevation model (DEMs) in the Maran-Sungi Lembing area, Malaysia. Electronic J Geotech Eng 15: 1–9.
   Google Scholar
• Adiri Z, El Harti A, Jellouli A, Lhissou R, Maacha L, Azmi M, Zouhair M, Bachaoui EM. 2017. Comparison of Landsat-8, ASTER and sentinel 1 satellite remote sensing data in automatic lineaments extraction: a case study of Sidi Flah-Bouskour inlier, Moroccan Anti Atlas. Adv Space Res. 60(11):2355–2367.
   Web of Science ®Google Scholar
• Ahmadi H, Pekkan E. 2021. Fault-based geological lineaments extraction using remote sensing and gis—a review. Geosciences (Switzerland). 11(5):183.
   Web of Science ®Google Scholar
• Ait Addi A, Chafiki D. 2013. Sedimentary evolution and palaeogeography of mid-Jurassic deposits of the Central High Atlas, Morocco. J Afr Earth Sci. 84:54–69.
   Web of Science ®Google Scholar
• Ait Brahim L, Chotin P, Hinaj S, Abdelouafi A, El Adraoui A, Nakcha C, Dhont D, Charroud M, Sossey Alaoui F, Amrhar M, et al. 2002. Paleostress evolution in the Moroccan African margin from Triassic to present. Tectonophysics. 357(1–4):187–205.
   Web of Science ®Google Scholar
• Allouban M, Karaoui B, Mahmoudi A, Baïdder L, Hafid A, Goodenough K, Eddebbi A. 2021. Petrographic and geochemical study of Jurassic-Cretaceous intrusive massifs (Gabbros-syenites) of the Eastern High Atlas, Morocco (Rich-Talsint axis). J Afr Earth Sci. 184:104280.
   Web of Science ®Google Scholar
• Arboleya ML, Teixell A, Charroud M, Julivert M. 2004. A structural transect through the High and Middle Atlas of Morocco. J Afr Earth Sci. 39(3-5):319–327.
   Web of Science ®Google Scholar
• Babault J, Teixell A, Struth L, Van Den Driessche J, Arboleya ML, Tesón E. 2013. Shortening, structural relief and drainage evolution in inverted rifts: insights from the Atlas Mountains, the eastern Cordillera of Colombia and the Pyrenees. Geol Soc Spec Publ. 377(1):141–158.
   Google Scholar
• Baghdadi N, Grandjean G, Lahondère D, Paillou P, Lasne Y. 2005. Apport de l’imagerie satellitaire radar pour l’exploration géologique en zones arides. Comptes Rendus - Geosci. 337(8):719–728.
   Google Scholar
• Beauchamp J. 1988. Triassic sedimentation and rifting in the high atlas (Morocco). Developments in geotectonics. Vol. 22. Amsterdam, Netherlands : Elsevier B.V.
   Google Scholar
• Bentahar I, Raji M. 2021. Comparison of Landsat OLI, ASTER, and Sentinel 2A data in lithological mapping: a case study of rich area (Central High Atlas, Morocco). Adv Space Res. 67(3):945–963.
   Web of Science ®Google Scholar
• Bentahar I, Raji M, Si Mhamdi H. 2020. Fracture network mapping using Landsat-8 OLI, sentinel-2A, ASTER, and ASTER-GDEM data, in the Rich area (Central High Atlas, Morocco). Arab J Geosci. 13(16):1–19. https://doi.org/10.1007/s12517-020-05736-6.
   Web of Science ®Google Scholar
• Chen J, Lin H, Pei Z. 2007. Application of ENVISAT ASAR data in mapping rice crop growth in southern China. IEEE Geosci Remote Sensing Lett. 4(3):431–435.
   Web of Science ®Google Scholar
• Coulibaly L. 1996. Interprétation structurale des linéaments par traitement d’images satellitaires: cas des sous-provinces d’Abitibi et d’Opatica. Département Géograph Télédétect Mémoire. 106. https://www.collectionscanada.gc.ca/obj/s4/f2/dsk2/ftp04/mq21736.pdf.
   Google Scholar
• Dubar G. 1949. Carte géologique provisoire du Haut Atlas de Midelt au 1/200 000. Notes et mémoires du service géologique du maroc, N°59bis, 1–56.
   Google Scholar
• El Alaoui El Moujahid H, Ibouh H, Bachnou A, Babram MA, El Harti A. 2016. Mapping and analysis of geological fractures extracted by remote sensing on Landsat TM images, example of the Imilchil-Tounfite area (central High Atlas, Morocco). Estudios Geol. 72(2):1–12.
   Google Scholar
• El Hajj M, Baghdadi N, Zribi M, Bazzi H, 2017. Synergic use of sentinel-1 and sentinel-2 images for operational soil moisture mapping at high spatial resolution over agricultural areas. Remote Sens. 9(12):1292.
   Google Scholar
• EL korchi A. 1981. Etude géologique de la boutonniére de Mougueur–El Bour (Haut Atlas oriental, Maroc). Paris: Université Pierre-et-Marie-Curie.
   Google Scholar
• El Qaydey J, Taj-Eddine K, Bonn F, Chikhaoui M, Witam O. 2006. Caractérisation lithologique du haut atlas marocain ÀL ’ aide des données D ’ aster et de mesures spectrales de terrain lithological characterization in the moroccan. Télédetection. 6:153–175.
   Google Scholar
• Farahbakhsh E, Chandra R, Olierook HKH, Scalzo R, Clark C, Reddy SM, Müller RD. 2020. Computer vision-based framework for extracting tectonic lineaments from optical remote sensing data. Int J Remote Sens. 41(5):1760–1787.
   Web of Science ®Google Scholar
• Frulla LA, Milovich JA, Karszenbaum H, Gagliardini DA. 1998. Radiometric corrections and calibration of SAR images. Int Geosci Remote Sens Symp (IGARSS), 2:1147–1149. https://doi.org/10.1109/igarss.1998.699700
   Google Scholar
• Guezal J, Baghdadi MEL, Barakat A, Rais J. 2011. Le magmatisme jurassique-crétacé de Béni-Mellal (Haut-Atlas central, Maroc): géochimie et signification géodynamique. Bull L’Inst Sci. 33(1981):17–23.
   Google Scholar
• Han L, Liu Z, Ning Y, Zhao Z. 2018. Extraction and analysis of geological lineaments combining a DEM and remote sensing images from the northern Baoji loess area. Adv Space Res. 62(9):2480–2493.
   Web of Science ®Google Scholar
• Hashim M, Ahmad S, Johari MAM, Pour AB. 2013. Automatic lineament extraction in a heavily vegetated region using Landsat Enhanced Thematic Mapper (ETM+) imagery. Adv Space Res. 51(5):874–890.
   Web of Science ®Google Scholar
• Henry JB, Chastanet P, Fellah K, Desnos YL. 2006. Envisat multi-polarized ASAR data for flood mapping. Int J Remote Sens. 27(10):1921–1929.
   Web of Science ®Google Scholar
• Hinaje S, Charroud M, Ait Brahim L, Arabi H, El Sabaoui A. 2015. Paleocontraintes mesozoiques, evolution tectonique et paleogeographie des bassins sedimentaires moyen atlasique et central haut atlasique marocains. ScienceLib Editions Mersenn, 7(May).
   Google Scholar
• Ibouh H. 2004. Du rift avorté au bassin sur décrochement, contrôles tectonique et sédimentaire pendant le Jurassique (Haut Atlas central, Maroc). Maroc: Université de Marrakech.
   Google Scholar
• Javhar A, Chen X, Bao A, Jamshed A, Yunus M, Jovid A, Latipa T. 2019. Comparison of multi-resolution optical Landsat-8, Sentinel-2 and radar Sentinel-1 data for automatic lineament extraction: a case study of Alichur area, SE Pamir. Remote Sens. 11(7):778–729.
   Google Scholar
• Jellouli A, El Harti A, Adiri Z, Chakouri M, El Hachimi J, Mostafa E. 2021. Remote sensing applications: society and environment application of optical and radar satellite images for mapping tectonic lineaments in kerdous inlier of the Anti-Atlas belt, Morocco. Remote Sens Appl: Soc Environ. 22(April):100509.
   Google Scholar
• Koita M, Jourde H, Ruelland D, Koffi K, Pistre S, Savane I. 2010. Cartographie des accidents régionaux et identification de leur rôle dans l’hydrodynamique souterraine en zone de socle. Cas de la région de Dimbokro-Bongouanou (Côte d’Ivoire). Hydrol Sci J. 55(5):805–820.
   Web of Science ®Google Scholar
• Lachkar N, Guiraud M, El Harfi A, Dommergues JL, Dera G, Durlet C. 2009. Early Jurassic normal faulting in a carbonate extensional basin: characterization of tectonically driven platform drowning (High Atlas rift, Morocco). J Geol Soc. 166(3):413–430.
   Google Scholar
• Laville E. 1985. Evolutions sédimentaire, tectonique et magmatique du bassin jurassique du Haut Atlas (Maroc): modèles en relais multiple de décrochements. FranceL University of Montpellier.
   Google Scholar
• Lhachmi A, Lorand JP, Fabries J. 2001. Petrogenesis of the Anemzi Mesozoic alakaline intrusion, central High Atlas, Morocco. J Afr Earth Sci. 32(4):741–764.
   Web of Science ®Google Scholar
• Liu Y, Gong W, Xing Y, Hu X, Gong J. 2019. ISPRS journal of photogrammetry and remote sensing estimation of the forest stand mean height and aboveground biomass in Northeast China using SAR Sentinel-1B, multispectral Sentinel-2A, and DEM imagery. ISPRS J Photogramm Remote Sens. 151():277–289.
   Web of Science ®Google Scholar
• Martín-Martín JD, Vergés J, Saura E, Moragas M, Messager G, Baqués V, Razin P, Grélaud C, Malaval M, Joussiaume R, et al. 2017. Diapiric growth within an early Jurassic rift basin: the Tazoult salt wall (central High Atlas, Morocco). Tectonics. 36(1):2–32.
   Web of Science ®Google Scholar
• Michard A, Ibouh H, Charrière A. 2011. Syncline-topped anticlinal ridges from the High Atlas: a Moroccan conundrum, and inspiring structures from the Syrian Arc, Israel. Terra Nova. 23(5):314–323.
   Web of Science ®Google Scholar
• Mondal S, Guha A, Pal SK. 2022. Comparative analysis of AVIRIS-NG and Landsat-8 OLI data for lithological mapping in parts of Sittampundi layered complex, Tamil Nadu, India. Adv Space Res. 69(3):1408–1426.
   Web of Science ®Google Scholar
• Nguemhe Fils SC, Bekele Mongo CH, Nkouathio DG, Mimba ME, Etouna J, Njandjock Nouck P, Nyeck B. 2018. Radarsat-1 image processing for regional-scale geological mapping with mining vocation under dense vegetation and equatorial climate environment, Southwestern Cameroon. Egypt J Remote Sens Space Sci. 21:S43–S54.
   Web of Science ®Google Scholar
• Othman AA, Gloaguen R. 2014. Improving lithological mapping by SVM classification of spectral and morphological features: the discovery of a new chromite body in the Mawat ophiolite complex (Kurdistan, NE Iraq). Remote Sens. 6(8):6867–6896.
   Google Scholar
• Ouanaimi H, Soulaimani A, Baidder L, Eddebbi A, Hoepffner C. 2018. Unraveling a distal segment of the West African Craton Paleozoic margin: stratigraphy of the Mougueur inlier of the eastern High Atlas, Morocco. Comptes Rendus - Geosci. 350(6):289–298.
   Web of Science ®Google Scholar
• Paloscia S, Member S, Pampaloni P, Pettinato S, Santi E. 2008. A comparison of algorithms for retrieving soil moisture from ENVISAT/ASAR images. IEEE Trans Geosci Remote Sens. 46(10):3274–3284.
   Web of Science ®Google Scholar
• Raj SK, Ahmed SA. 2014. Lineament extraction from southern Chitradurga Schist belt using landsat TM, ASTERGDEM and geomatics techniques. Int J Comput Appl. 93(12):12–20.
   Google Scholar
• Rutzinger M, Maukisch M, et al. 2007. Development of algorithms for the extraction of linear patterns (lineaments) from airborne laser scanning data. In Kellerer-Pirklbauer A, Keiler M, Embleton-Hamann C, Stotter J, editor. Geomorphology for the future: Obergurgl, Austria, Setember 2–7, 2007; Conference Proceedings. Innsbruck: Innsbruck University Press; p. 161–168.
   Google Scholar
• Sedrette S, Rebai N, Turki M. 2015. Développement d’une approche quantitative d’extraction semi-automatique des accidents tectoniques de la carte géologique de Nefza au 1 /50 000 en format shp. Arab J Earth Sci. 2(2):53–64.
   Google Scholar
• Sedrette S. 2016. Automatic extraction of lineaments from Landsat Etm + images and their structural interpretation: case study in Nefza region (North West of Tunisia) Automatic extraction of lineaments from Landsat Etm + images and their structural interpretation: case. September 2018.
   Google Scholar
• Sedrette S, Rebaï N. 2016. Automatic extraction of lineaments from Landsat Etm + images and their structural interpretation: case study in Nefza region (North West of Tunisia). J Res Environ Earth Sci. 4(2016):139–145. http://earthexplorer.usgs.gov.
   Google Scholar
• Snoeij P, Brown M, Davidson M, Rommen B, Floury N, Geudtner D, Torres R. 2011. Sentinel-1A and sentinel-1B CSAR status. Proc SPIE. 8179.
   Google Scholar
• Steinhausen MJ, Wagner PD, Narasimhan B, Waske B. 2018. Combining sentinel-1 and Sentinel-2 data for improved land use and land cover mapping of monsoon regions. Int J Appl Earth Observ Geoinform. 73(August):595–604.
   Google Scholar
• Tagnon BO, Assoma VT, Mangoua JMO, Douagui AG, Kouamé FK, Savané I. 2020. Contribution of SAR/RADARSAT-1 and ASAR/ENVISAT images to geological structural mapping and assessment of lineaments density in Divo-Oume area (Côte d’Ivoire). Egypt J Remote Sens Space Sci. 23(2):231–241.
   Web of Science ®Google Scholar
• Teixell A, Arboleya ML, Julivert M, Charroud M. 2003. Tectonic shortening and topography in the central High Atlas (Morocco). Tectonics. 22(5):n/a–n/a.
   Web of Science ®Google Scholar
• Teixell A, Barnolas A, Rosales I, Arboleya ML. 2017. Structural and facies architecture of a diapir-related carbonate minibasin (lower and middle Jurassic, High Atlas, Morocco). Mar Pet Geol. 81:334–360.
   Web of Science ®Google Scholar
• Yao KT, Oga M, Kouadio KE, Fouché O, Ferriere G. 2014. Rôle hydrogéologique des linéaments structuraux en milieu cristallin et cristallophyllien: cas du bassin versant du Sassandra, Sud-Ouest de la Côte d’Ivoire. Afr Sci Rev Int Sci Technol. 10(4):78–92.
   Google Scholar