Refine your search
Collections
Co-Authors
Journals
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
Jain, Ronak
- Presence of base metals in the southern extension of Zawarmala Dolomite, Udaipur, Rajasthan, India
Abstract Views :308 |
PDF Views:104
Authors
Affiliations
1 Department of Geology, Faculty of Earth Sciences, Mohanlal Sukhadia University, Udaipur 313 001, India
1 Department of Geology, Faculty of Earth Sciences, Mohanlal Sukhadia University, Udaipur 313 001, India
Source
Current Science, Vol 121, No 7 (2021), Pagination: 962-966Abstract
This communication reports the presence of lead (Pb), zinc (Zn) and copper (Cu) mineralization in the dolomite rocks found in the southern part of the Zawarmala which is a well-known carbonate hosted Pb–Zn deposit occurring in the Zawar region in the south of Udaipur, Rajasthan, India. Remote sensing data analysis indicated the southern extension of the Zawarmala dolomite till Dhelai village where the outcrop truncates by the E–W fault. The carbonate with malachite strains supported by field evidences and petrological, ore microscopic, XRF and evidence of the presence of the trace elements reveal the presence of base metals in this area. The extension of occurrence of these dolomites rocks may be explored further for investigation of base metal mineralization in this regionKeywords
ASTER, base metal, carbonates/dolomites, ore microscopy, trace elements, ZawarmalaReferences
- Roy, A. B. and Jakhar, S. R., Geology of Rajasthan (Northwest India): Precambrian to Recent, Scientific Publishers (India), Jodhpur, 2002.
- Roy, A. B., Paliwal, B. S., Shekhawat, S. S., Nagori, D. K., Golani, P. R. and Bejarniya, B. R., Stratigraphy of the Aravalli Supergroup in the type area. In Precambrian of the Aravalli Mountain, Rajasthan, India (ed. Roy, A. B.), Memoir of the Geological Society of India, 1988, pp. 121–131.
- Gupta, S. N. et al., The Precambrian Geology of the Aravalli region, Southern Rajasthan and North-eastern Gujarat. Mem. Geol. Surv. India, 1997, 123, 1–262.
- GSI, Geology and Mineral Resources of Rajasthan, Miscellaneous Publication, No. 30, Part 12, Geological Survey of India, Western Region, India, 2011, 3rd edn.
- Jain, R., Bhu, H. and Purohit, R., Application of thermal remote sensing technique for mapping of ultramafic, carbonate and siliceous rocks using ASTER data in Southern Rajasthan, India. Curr. Sci., 2020, 119, 954–961.
- Roy, A. B. and Jain, A. K., Polyphase deformation in the Pb–Zn bearing Precambrian rocks of Zawarmala, Udaipur district, southern Rajasthan. Q. J. Geol. Min. Metall. Soc. India, 1974, 46, 81–86.
- Singh, N. N., Structure and its bearing on the Sulphide Mineralization at Zawarmala (Zawar mines), Udaipur (Rajasthan), India, University of Rajasthan, Jaipur, 1982.
- Singh, N. N., Tectonic and stratigraphic framework of the leadzinc sulphide mineralisation at Zawarmala, District Udaipur, Rajasthan. J. Geol. Soc. India, 1988, 31, 546–564.
- Vidyarthi, R. C. and Sen, R., Baroi–Zawarmala lead–zinc deposits, Zawar belt, Udaipur, Rajasthan, India. In Proceedings of Tectonics and Metallogeny of South and East Asia Geological Survey of India, Miscellaneous Publication No. 34, Calcutta, India, 1978, pp. 118–134.
- Samar, M. S., Singh, N. N. and Hedge, M. P., Lead zinc mineralization in central part of Zawarmala, Zawar mines, Rajasthan. Abstract. In Discussion on Development for Basemetal (CopperLead-Zinc) deposits in Rajasthan and Gujarat, 1975.
- Samar, M. S. and Singh, N. N., Geology and planned exploration of Zawarmala lead–zinc deposit. Abstract. In Indian Geological Congress, Udaipur, 1978, pp. 45–46.
- Roy, A. B., Geometry and evolution of superposed folding in the Zawar lead–zinc mineralized belt, Rajasthan. Proc. Indian Acad. Sci. (Earth Planet. Sci.), 1995, 104, 349–371.
- Talluri, J. K., Pandalai, H. S. and Jadhav, G. N., Fluid chemistry and depositional mechanism of the epigenetic, discordant ores of the proterozoic, carbonate-hosted, Zawarmala Pb–Zn deposit, Udaipur District, India. Econ. Geol., 2000, 95, 1505–1525.
- Jain, R., Kumar, A. and Sharma, R. U., Study of mineral mapping techniques: a case study in southeastern Rajasthan. In Proceedings of 38th Asian Conference on Remote Sensing – Space Applications: Touching Human Lives, ACRS Curran Associates, Inc., New York, New Delhi, India, 2017, pp. 2799–2807.
- Jain, R., Kumar, A. and Sharma, R. U., Study of Mineral Mapping Techniques using Airborne Hyperspectral Data: Exploring the Potential of AVIRIS-NG for Mineral Identification, Lap Lambert Academic Publishing, Germany, 2018.
- Jain, R. and Sharma, R. U., Airborne hyperspectral data for mineral mapping in Southeastern Rajasthan, India. Int. J. Appl. Earth Obs. Geoinf., 2019, 81, 137–145.
- Guha, A., Chattoraj, S. L., Chatterjee, S., Vinod Kumar, K., Rao, P. V. N. and Bhaumik, K., Reflectance spectroscopy-guided broadband spectral derivative approach to detect glauconite-rich zones in fossiliferous limestone, Kachchh region, Gujarat, India. Ore Geol. Rev., 2020, 127, 103825.
- Rani, K., Guha, A., Vinod Kumar, K., Bhattacharya, B. K. and Pradeep, B., Potential use of airborne hyperspectral AVIRIS-NG data for mapping proterozoic metasediments in Banswara, India. J. Geol. Soc. India, 2019, 95, 152–158.
- Guha, A., Yamaguchi, Y., Chatterjee, S., Rani, K. and Vinod Kumar, K., Emittance spectroscopy and broadband thermal remote sensing applied to phosphorite and its utility in geoexploration: a
- study in the parts of Rajasthan, India. Remote Sensing, 2019, 11,1003.
- Jain, R. and Sharma, R. U., Mapping of mineral zones using the spectral feature fitting method in Jahazpur belt, Rajasthan, India. Int. Res. J. Eng. Technol., 2018, 5, 562–567.
- Hewson, R. D., Cudahy, T. J., Mizuhiko, S., Ueda, K. and Mauger, A. J., Seamless geological map generation using ASTER in the Broken Hill-Curnamona province of Australia. Remote Sensing Environ., 2005, 99, 159–172.
- Kalinowski, A. and Oliver, S., ASTER Mineral Index Processing Manual, Australia, 2004.
- Straczek, J. A. and Srikantan, B., The geology of the Zawar lead–zinc area, Rajasthan, India. Mem. Geol. Surv. India, 1966, 92, 1–85.
- Smith, A. W., Remobilization of sulfide orebodies. Econ. Geol.,1964, 59, 930–935.
- Poddar, B. C., Lead–zinc mineralization in the Zawar Belt, India –discussion. Econ. Geol., 1965, 60, 636–638.
- Roy, A. B. et al., Lithostratigraphy and tectonic evolution of theAravalli Supergroup: a protogeosynclinal sequence. In Rift Basins and Aulacogens (ed. Casshyap, S. M.), Gyanodaya Prakashan, Nainital, 1993, pp. 73–90.
- GSI, Udaipur Quadrangle. Geological Survey of India, 1999.
- Application of Thermal Remote Sensing Technique for Mapping ofUltramafic, Carbonate and Siliceous Rocks using ASTER Data in Southern Rajasthan, India
Abstract Views :306 |
PDF Views:122
Authors
Affiliations
1 Department of Geology, Faculty of Earth Sciences, Mohanlal Sukhadia University, Udaipur 313 001, IN
1 Department of Geology, Faculty of Earth Sciences, Mohanlal Sukhadia University, Udaipur 313 001, IN
Source
Current Science, Vol 119, No 6 (2020), Pagination: 954-961Abstract
In the present study, thermal remote sensing technique and ASTER data have been used to delineate ultramafic, carbonate and siliceous rocks. The study gains importance as mineralized carbonate and ultramafic rocks are present in the southern region of Rajasthan, India between Udaipur and Dungarpur districts. The rocks in the study area include phyllites, mica schist, chlorite schist, quartzite, dolomite, granite, granitoids, gneiss and intrusive serpentinite. ASTER thermal bands were used to map ultramafics, siliceous and carbonate rocks on a scale of 1 : 380,000. Delineation of ultramafics was done using MRI-AV and MI-N indices, however the former provided a more informative map compared to the latter. QRIAV, QI-N and QI-RH indices were used for mapping siliceous rock. QI-RH provided a more informative map compared to QRI-AV and QI-N. The index used for carbonate rocks was CI-N, but this did not provide a satisfactory map.Keywords
ASTER TIR, Carbonate and Siliceous Rocks, Thermal Indices, Thermal Remote Sensing, Ultramafics.References
- Lyon, R. J. P., Infrared spectral emittance in geological mapping: airborne spectrometer data from Pisgah Crater, California. Science, 1972, 175, 983–986.
- Salisbury, J. W. and Walter, L. S., Thermal infrared (2.5–13.5 μm) spectroscopic remote sensing of igneous rock types on particulate planetary surfaces. J. Geophys. Res., 1989, 94, 9192–9202.
- Guha, A., Yamaguchi, Y., Chatterjee, S., Rani, K. and Vinod Kumar, K., Emittance spectroscopy and broadband thermal remote sensing applied to phosphorite and its utility in geoexploration: a study in the parts of Rajasthan, India. Remote Sensing, 2019, 11, 1003.
- Kahle, A. B., Gillespie, A. R. and Goetz, A. F. H., Thermal inertia imaging: a new geologic mapping tool. Geophys. Res. Lett., 1976, 3, 419–421.
- Salisbury, J. W. S. and D’Aria, D. M., Emissivity of terrestrial materials in the 8–14 μm atmospheric windows. Remote Sensing Environ., 1992, 42, 83–106.
- Guha, A. and Vinod Kumar, K., New ASTER derived thermal indices to delineate mineralogy of different granitoids of an Archaean craton and analysis of their potentials with reference to Ninomiya’s indices for delineating quartz and mafic minerals of granitoids – an analysis in Dharwar Craton. Ore Geol. Rev., 2016, 74, 76–87.
- Ninomiya, Y., Fu, B. and Cudahy, T. J., Detecting lithology with advanced spaceborne thermal emission and reflection radiometer (ASTER) multispectral thermal infrared ‘radiance-at-sensor’ data. Remote Sensing Environ., 2005, 99, 127–139.
- Ding, C., Liu, X., Liu, W., Liu, M. and Li, Y., Mafic–ultramafic and quartz-rich rock indices deduced from ASTER thermal infrared data using a linear approximation to the Planck function. Ore Geol. Rev., 2014, 60, 161–173.
- Ding, C., Li, X., Liu, X. and Zhao, L., Quartzose–mafic spectral feature space model: a methodology for extracting felsic rocks with ASTER thermal infrared radiance data. Ore Geol. Rev., 2015, 66, 283–292.
- Rani, K., Guha, A., Pal, S. K. and Vinod Kumar, K., Comparative analysis of potentials of ASTER thermal infrared band derived emissivity composite, radiance composite and emissivity–temperature composite in geological mapping of Proterozoic rocks in parts Banswara, Rajasthan. J. Indian Soc. Remote Sensing, 2018, 46, 771–782.
- Van der Meer, F. D. et al., Multi- and hyperspectral geologic remote sensing: a review. Int. J. Appl. Earth Obs. Geoinf., 2012, 14, 112–128.
- Gillespie, A. R., Lithologic mapping of silicate rocks using TIMS. In Proceedings of the Thermal Infrared Multispectral Scanner Data User’s Workshop, Pasadena, CA, 1985, pp. 29–44.
- Gupta, S. N. et al., The Precambrian geology of the Aravalli region, southern Rajasthan and north-eastern Gujarat. Mem. Geol. Surv. India, 1997, 123, 1–262.
- Sinha-Roy, S., Malhotra, G. and Mohanty, M., Geology of Rajasthan, Geological Society of India, Bangalore, 1998.
- Roy, A. B. and Jakhar, S. R., Geology of Rajasthan (Northwest India): Precambrian to Recent, Scientific Publishers (India), Jodhpur, 2002.
- Bhu, H., Sarkar, A., Purohit, R. and Banerjee, A., Characterization of fluid involved in ultramafic rocks along the Rakhabdev Lineament from southern Rajasthan, northwest India. Curr. Sci., 2006, 91, 1251–1256.
- Purohit, R., Bhu, H., Sarkar, A. and Ram, J., Evolution of the ultramafic rocks of the Rakhabdev and Jharol belts in southeastern Rajasthan, India: new evidences from imagery mapping, petrominerological and OH stable isotope studies. J. Geol. Soc. India, 2015, 85, 331–338.
- Abrams, M., The Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER): data products for the high spatial resolution imager on NASA’s Terra platform. Int. J. Remote Sensing, 2000, 21, 847–859.
- Yamaguchi, Y., Kahle, A. B., Tsu, H., Kawakami, T. and Pniel, M., Overview of Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER). IEEE Trans. Geosci. Remote Sensing, 1998, 36, 1062–1071.
- Zhang, X., Pazner, M. and Duke, N., Lithologic and mineral information extraction for gold exploration using ASTER data in the south Chocolate Mountains (California). ISPRS J. Photogramm. Remote Sensing, 2007, 62, 271–282.
- Gomez, C., Delacourt, C., Allemand, P., Ledru, P. and Wackerle, R., Using ASTER remote sensing dataset for geological mapping in Namibia. Phys. Chem. Earth, Parts A/B/C, 2005, 30, 97–108.
- Kalinowski, A. and Oliver, S., ASTER Mineral Index Processing Manual, Remote Sensing Applications, Geoscience, Australia, 2004.
- Matar, S. S. and Bamousa, A. O., Integration of the ASTER thermal infra-red bands imageries with geological map of Jabal Al Hasir area, Asir Terrane, the Arabian Shield. J. Taibah Univ. Sci., 2013, 7, 1–7.
- Ninomiya, Y. and Fu, B., Regional lithological mapping using ASTER-TIR data: case study for the Tibetan Plateau and the surrounding area. Geosciences, 2016, 6, 39.
- Rajendran, S. and Nasir, S., ASTER spectral sensitivity of carbonate rocks – study in Sultanate of Oman. Adv. Space Res., 2014,
- , 656–673.
- Rowan, L. C., Mars, J. C. and Simpson, C. J., Lithologic mapping of the Mordor, NT, Australia ultramafic complex by using the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER). Remote Sensing Environ., 2005, 99, 105–126.
- Ninomiya, Y. and Fu, B., Thermal infrared multispectral remote sensing of lithology and mineralogy based on spectral properties of materials. Ore Geol. Rev., 2019, 108, 54–72.
- Pour, A. B. et al., Mapping listvenite occurrences in the damage zones of northern Victoria Land, Antarctica using ASTER satellite remote sensing data. Remote Sensing, 2019, 11, 1408.
- Yao, K., Pradhan, B. and Idrees, M. O., Identification of rocks and their quartz content in Gua Musang goldfield using advanced spaceborne thermal emission and reflection radiometer imagery. J. Sensors, 2017, 2017, 6794095-1–6794095-8.
- Rockwell, B. W. and Hofstra, A. F., 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, 2008, 4, 218–246.
- Yajima, T. and Yamaguchi, Y., Geological mapping of the Francistown area in northeastern Botswana by surface temperature and spectral emissivity information derived from Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) thermal infrared data. Ore Geol. Rev., 2013, 53, 134–144.
- Son, Y. S., Kang, M. K. and Yoon, W. J., Lithological and mineralogical survey of the Oyu Tolgoi region, southeastern Gobi, Mongolia using ASTER reflectance and emissivity data. Int. J. Appl. Earth Obs. Geoinf., 2014, 26, 205–216.