Extracting clay minerals with emphasis on Bentonite in Eastern Iran, using Landsat 8 and ASTER images
الموضوعات :
Saeed Saadat
1
,
Maliheh Ghoorchi
2
,
Rahim Dabiri
3
1 - Department of Petroleum Engineering and Geology, Mashhad Branch, Islamic Azad University, Mashhad, Iran
2 - Department of Petroleum Engineering and Geology, Mashhad Branch, Islamic Azad University, Mashhad, Iran
3 - Department of Petroleum Engineering and Geology, Mashhad Branch, Islamic Azad University, Mashhad, Iran
تاريخ الإرسال : 04 الإثنين , جمادى الأولى, 1444
تاريخ التأكيد : 10 الأربعاء , رجب, 1444
تاريخ الإصدار : 13 السبت , ذو الحجة, 1444
الکلمات المفتاحية:
bentonite,
remote sensing,
Iran,
Clay Minerals,
ملخص المقالة :
The prospecting area is located in the eastern part of Iran. Aster and Landsat 8 satellite images were processed with different spectral analyses techniques to detect the clay representing the alteration zones, with emphasis on bentonite occurrences in the study area. Band ratio (BR), Spectral Angle Mapper (SAM), Mixture Tuned Matched Filtering (MTMF), Principal Component Analysis (PCA), Spectral Feature Fitting (SFF), and Least Square Fit (LS-Fit) techniques were performed to show the promising areas for clay mineral. Band ratios of 6/7, 6/5, and 4/2 from Landsat 8 OLI imagery and 4/6, 5/6, 5/8, from ASTER were used to enhance clay alterations. The results obtained from the supervised classification using the SAM algorithm for minerals from US Geological Survey spectral library (USGS) have been compared with the results of Jet Propulsion Laboratory (JPL) spectral library. The Sequential Maximum Angle Convex Cone (SMACC) algorithm also performed to detect same minerals. Comparing the different analyzing satellite image based on ASTER data indicate all methods generate relatively similar results for clay mineral. Although all methods generate relatively similar results, the SAM method seems to be the best fit with geological evidences to generate reliable promising areas for clay mineral in this area. Based on this study, around 100 km2 of the total studied area was selected as suitable for more exploration and ground survey.
المصادر:
Abrams MJ, Brown D, Lepley L, Sadowski R (1983) Remote sensing for porphyry copper deposits in southern Arizona, Economic Geology 78:591–604.
Aisabokhae J, Osazuwa I (2021) Radiometric mapping and spectral based classification of rocks using remote sensing data analysis: The Precambrian basement complex, NW Nigeria, Remote Sensing Applications: Society and Environment 21, 100447.
Bishop JL, Michalski JR, Carter J (2017) Remote detection of clay minerals. In Developments in clay science 8:482-514.
Boardman JW, Kruse FA (1994) Automated spectral analysis: a geological example using AVIRIS data, north Grapevine Mountains, Nevada. Proceedings of the Thematic Conference on Geologic Remote Sensing.
Clark RN (1999) Spectroscopy of rocks and minerals, and principles of spectroscopy. Man. Remote Sens 3 (3-58):2-2.
Crosta AP, De Souza Filho CR, Azevedo F, Brodie C (2003) Targeting key alteration minerals in epithermal deposits in Patagonia, Argentina, using ASTER imagery and principal component analysis. Int J Remote Sens 24(21):4233–4240.
Dennison PE, Halligan KQ, Roberts DA (2004) A comparison of error metrics and constraints for multiple endmember spectral mixture analysis and spectral angle mapper, Remote Sens. Environ. 93:359–367.
Ducasse E, Adeline K, Briottet X, Hohmann A, Bourguignon A, Grandjean G (2020) Montmorillonite estimation in clay–quartz–calcite samples from laboratory SWIR imaging spectroscopy: A comparative study of spectral pre-processing and unmixing methods, Remote Sensing 12(11):1723.
Fatima K, Khattak MUK, Kausar AB, Toqeer M, Haider N, Rehman AU (2017) Minerals identification and mapping using ASTER satellite image, Journal of Applied Remote Sensing 11:46006.
Green AA, Berman M, Switzer P, Craig MD (1988) A Transformation for Ordering Multispectral Data in Terms of Image Quality with Implications for Noise Removal, IEEE Transactions on Geoscience and Remote Sensing 26: 65–74.
Hejazi M, Ghorbani M (2013) Geology of Iran (bentonite and zeolite deposits), Geological Survey and Mineral Exploration of Iran 108 p.
Jiang T, Werff H, Meer F (2020) Classification Endmember Selection with Multi-Temporal Hyperspectral Datam Remote Sens 15;12(10):1575.
Karimpour M, Malek Zadeh Shafaroodi A (2016) Satellite Mineral Mapping for Recognition of Sodic and Calcic Type Bentonite Deposits in Eastern Iran, Advanced Applied Geology 6(3):84-96.
Karimpour MH, Stern CR, Farmer L, Saadat S, Malekezadeh A (2011) Review of age, Rb-Srgeochemistry and petrogenesis of Jurassic to Quaternary igneous rocks in Lut Block, Eastern Iran, Geopersia 1(1):19-36.
Kruse FA, Lefkoff AB, Boardman JW, Heidebrecht KB, Shapiro AT, Barloon PJ, Goetz AFH (1993) The spectral image processing system (SIPS)-interactive visualization and analysis of imaging spectrometer data, Remote Sens. Environ 44:145-163.
Laeiq A, Tahir S, Khan SD (2016) Reflectance spectroscopy and remote sensing data for finding sulfidebearing alteration zones and mapping geology in GilgitBaltistan, Pakistan, Earth Sci. Inform 9(1): 113-121.
Lamrani O, Aabi A, Boushaba A, Seghir MT, Adiri Z, Samaoui S (2021) Bentonite clay minerals mapping using ASTER and field mineralogical data: A case study from the eastern Rif belt, Morocco, Remote Sensing Applications: Society and Environment 24:100640.
Mars JC, Rowan LC (2006) Regional mapping of phyllic- and argillic-altered rocks in the zagros magmatic arc, Iran, using advanced spaceborne thermal emission and reflection radiometer (ASTER) data and logical operator algorithms, Geosphere 2:161–186.
Mars JC, Rowan LC (2011) ASTER spectral analysis and lithologic mapping of the Khanneshin carbonatite volcano, Afghanistan, Geosphere 7(1): 276–289.
Modabberi S, Namayandeh A, Setti M, López-Galindo A (2019) Genesis of the Eastern Iranian bentonite deposits, Applied Clay Science 168:56-67.
Mundt JT, Streutker DR, Glenn NF (2007) Partial Unmixing of Hyperspectral Imagery: Theory and methods, ASPRS Annual Conference Tampa, Florida 1-12.
Nakhaei M, Mohammadi SS, Rasa I, Samiee S (2019) Study of mineralogy, geochemistry and elemental behavior in the process of bentonites formation in Sarbisheh area (South Khorasan, east of Iran), Iranian Journal of Crystallography and Mineralogy 27(1):207-220.
Navai I (1974) Geological map of Sahl-abad, sheet 7954, scale 1:100,000, Geological Survey of Iran, Tehran.
Nazari H, Salamti R (1999) Geological map of Sarbisheh, sheet 7955, scale 1:100,000, Geological Survey of Iran, Tehran.
Rockwell BW, Hofstra AH (2008) Identification of quartz and carbonate minerals across northern Nevada using ASTER thermal infrared emissivity data—Implications for geologic mapping and mineral resource investigations in well-studied and frontier areas, Geosphere 4(1):218-246.
Rowan LC, Mars JC (2003) Lithologic mapping in the Mountain Pass, California area using advanced spaceborne thermal emission and reflection radiometer (ASTER) data, Remote sensing of Environment 84(3):350-366.
Sample-Lord KM, Ahmed M, Malusis MA (2021) Diffusion through soil-bentonite backfill from a constructed vertical cutoff wall, Soils Found 61:429–443.
Saadat S, Ghoorchi M (2021) Exploration of industrial minerals (remote sensing, geochemistry, geophysics, geology and environment), Islamic Azad University Publications, Mashhad branch, 536 pp.
Sarp G (2005) Lineament analysis from satellite images, north-west of Ankara, Master's thesis, Middle East Technical University.
Vural A, Akpinar İ, Sipahi F (2021) Mineralogical and Chemical Characteristics of Clay Areas, Gümüşhane Region (NE Turkey), and Their Detection Using the Crósta Technique with Landsat 7 and 8 Images, Nat Resour Res 30:3955–3985.
Zhou Q, Jing Z, Jiang S (2003) Remote Sensing Image Fusion for Different Spectral and Spatial Resolutions with Bilinear Resampling Wavelet Transform, In Proceedings of the IEEE Conference on Intelligent Transportation Systems (ITSC) Shanghai, China 2:1206–1213.