Abstract
In the present study, an attempt was made to analyse the reflectance spectra of kimberlites to evaluate its potential as key in remote sensing based spatial mapping. The spectral profiles of kimberlite samples were collected within the visible-near infrared-shortwave infrared (VNIR-SWIR) electromagnetic domain. In this regard, we analysed the reflectance spectra of three kimberlite pipes (having variable mineralogy) of Narayanpet kimberlite field (NKF) based on the comparative analysis of spectral features of kimberlite samples with the spectral features of their dominant constituent minerals. The relative abundances of each of the constituent minerals were confirmed using semiquantitative mineralogical data from X-ray diffraction analysis. This was supplemented with petrographical data as reference. We found that the absorption features imprinted in the reflectance spectra of kimberlites were mineralogically sensitive. These spectral features were imprinted by spectral features of serpentine, olivine, and calcite depending on the relative dominance of these minerals in kimberlites. With regard to understand the spectral behaviour of weathered residue of kimberlite for targeting buried kimberlite, we also attempted a comparative analysis of spectral profiles of in-situ soil developed above the pipes with the spectra of respective kimberlites in NKF area. While comparing aforementioned spectra, it was observed that the spectral signatures of NKF kimberlites were broadly translated to the in-situ soil. Further, we compared the spectral profiles of selected NKF kimberlites with the spectra of three distinct kimberlite pipes of Wajrakarur kimberlite field (WKF) characterised with similar mineralogy with respect to the selected NKF pipes. Relative dominance of constituent minerals (i.e., serpentine, olivine, calcite, etc.) in these pipes was taken as reference to identify the mineralogical similarity of the pipes of both the field. It was observed that the spectral profiles of NKF and WKF kimberlites were highly correlated with regard to wavelength of diagnostic absorption features. Finally, we also made an attempt to understand the effect of spectral mixing, in spectral separation of kimberlites and associated granite-granodiorite gneiss (i.e., Dharwar Gneiss). It was seen that the spectral contrast of kimberlite and gneiss was dependent on the relative size of the pipe with respect to pixel or ground sampling diameter of spectral data acquisition. Study confirmed the diagnostic nature of reflectance spectra of pipes along with their mineralogical sensitiveness and spatial integrity. It also highlighted how spectral mixing can influence the spectral feature based remote detection of kimberlites.
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References
ASD Inc (2012) Field spec specification, (www.asdi.com) (Date of access: 19–04–2012)
Babu TM (1998) Diamonds in India. Geological Society of India, Bangalore
Baldridge AM, Hook SJ, Grove CI, Rivera G (2009) The ASTER spectral library version 2.0. Remote Sens Environ 113:711–715
Bose MK (1997) Igneous Petrology, First Edition ed. World Press, Kolkata
Bruegge CJ, Chrien N, Haner D (2001) A Spectralon BRF database for MISR calibration applications. Remote Sens Environ 76:354–366
Chetty TRK (2005) Structural and Tectonic perspectives of Kimberlites and Related Rocks in the Indian Peninsula” Group discussion on Kimberlites and related rocks of India. J Geol Soc India Spec Publ:23–24
Clark RN (2011) USGS spectral laboratory,(http://speclab.cr.usgs.gov/spectrallib.html),(Date of access: 11–04–11)
Cloutis EA (1996) Review article hyperspectral geological remote sensing: evaluation of analytical techniques. Int J Remote Sens 17:2215–2242
Cloutis EA, Klima RL, Kaletzke L, Coradini A, Golubeva LF, McFadden LA, Shestopalov DI, Vilas F (2010) The 506nm absorption feature in pyroxene spectra: nature and implications for spectroscopy-based studies of pyroxene-bearing targets. Icarus 207:295–313
Drury SA, Harris NBW, Holt RW, Reeves-Smith GJ, Wightman RT (1984) Precambrian tectonics and crustal evolution in south India. J Geol 92:3–20
Goetz AFH (2009) Remote sensing of environment three decades of hyperspectral remote sensing of the earth: a personal view. Remote Sens Environ 113:S5–S16
Goetz AFH, Rock BN, Rowan LC (1983) Remote sensing for exploration: an overview. Econ Geol 78:573–590
Guha A, Chakraborty D, Ekka AB, Pramanik K, Vinod Kumar K, Chatterjee S, Subramanium S, Rao A (2012a) Spectroscopic study of rocks of Hutti-Maski schist belt, Karnataka. J Geol Soc India 79:335–344
Guha A, Rao A, Ravi S, Vinod Kumar K, Dhananjaya Rao EN (2012b) Analysis of the potentials of kimberlite rock spectra as Spectral end member—a case study using kimberlite rock Spectra from the Narayanpet kimberlite Field (NKF), Andhrapradesh. Curr Sci 103:1096–1104
Haggerty SE (2005) Kimberlite-clan rocks in India: Significance of new Volcanological, Geochemical and Petrological (VGP) observations” Group discussion on Kimberlites and related rocks of India. J Geol Soc India Spec Publ:8–9
Kaminsky FV (2005) Prognostication of primary Diamond Deposits in India. Group discussion on Kimberlites and related rocks of India. J Geol Soc India Spec Publ:11–12
Kruse FA (2011) Mapping surface mineralogy using imaging spectrometry. Geomorphology
Kruse FA, Boardman JW (2000) Characterization and mapping of kimberlites and related diatremes using hyperspectral remote sensing. IEEE Aerospace Conf Proc Big Sky MT, pp. 299–304.
Mitchell RH (2005) Potassic magmas derived from metasomatised lithospheric mantle: Nomenclature and relevance to diamond potential. Group discussion on Kimberlites and related rocks of India. J Geol Soc India Spec Publ:3–4
Mitchell RH (2008) Petrology of hypabyssal kimberlites: Relevance to primary magma compositions. J Volcanol Geotherm Res 174:1–8
Murthy DSN, Dayal AM (2001) Geochemical characteristics of kimberlite rock of the Anantapur and Mahbubnagar districts, Andhra Pradesh, South India. J Asia Earth Sci 19:311–319
Neelakantam S (2001) Exploration for diamond in southern India. Geol Surv India Spl. Publ:521–555
Nicodemus FF, Richmond JC, Hsia JJ, GIinsberg IW, Limperis TL (1977) Geometrical considerations and nomenclature for reflectance. National Bureau of Standards Monograph, Washington, p. 20402
Okada K, Iwashita A (1992) Hyper-multispectral image analysis based on waveform characteristics of spectral curve. Adv Space Res 12:433–442
Paul DK, Nayak SS (2006) Indian kimberlites and related rocks: petrology and geochemistry. J Geol Soc India 67:328–356
Paul DK, Nayak SS, Pant NC (2005) Indian Kimberlites and Related Rocks: Petrology and Geochemistry” Group discussion on Kimberlites and related rocks of India. J Geol Soc India Spec Publ
Podvysotskiy VT (1985) Serpentine and carbonate mineralisation in the kimberlites. Int Geol Rev 27:810–823
Rao CNV (2005) Kimberlite, lamprorite and related rock studies in India: present status, key issues and future prospects, group discussion on kimberlites and related rocks of India. Geol Soc India Spec Publ 2005:15–22
Rao KRP, Reddy TAK, Rao KVS, Rao KSB, Rao NV (1998) Geology, petrology and geochemistry of Narayanpet kimberlites in Andhra Pradesh and Karnataka. J Geol Soc India 52:663–676
Rao NVC, Paton C, Lehmann B (2012) Origin and diamond prospectivity of Mesoproterozoic kimberlites from the Narayanpet field, Eastern Dharwar Craton, southern India: insights from groundmass mineralogy, bulk-chemistry and perovskite oxybarometry. Geol J 47:186–212
Roach LH, Mustard J, Gendrin A, Fernández-Remolar D, Amils R, Amaral-Zettler L (2006) Finding mineralogically interesting targets for exploration from spatially coarse visible and near IR spectra. Earth Planet Sci Lett 252:201–214
Sabins FF (1999) Remote sensing for mineral exploration. Ore Geol Rev 14:157–183
Schumacher JC (2012) Serpentine in kimberlite: an indicator of water rich primary or externally-derived fluid? Eur Mineral Conf 1:593
Tukiainen T, Thorning L (2005) Detection of kimberlitic rocks in west Greenland using airborne hyperspectral data. The HyperGreen 2002 project geological survey of Denmark and Greenland. Geol Surv Denmark Greenl Bull 7:69–72
van der Meer F (2004) Analysis of spectral absorption features in hyperspectral imagery. Int J Appl Earth Obs Geoinf 5:55–68
van der Meer FD, de Jong SM, Bakker WH (2001) Imaging spectrometry: basic analytical techniques In: Van der meer, F.d., and De Jong, S.M (Ed.), Imaging spectrometry: basic principles and prospective applications. Springer-Verlag, pp. 15–61
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Authors are grateful to Dr. V.K. Dadhwal for his encouragement and support. Authors are also grateful to Deputy Director General, GSI, Operation Andhra Pradesh for approving this collaborative research.
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Guha, A., Kumar, K.V., Ravi, S. et al. Reflectance spectroscopy of kimberlites—in parts of Dharwar Craton, India. Arab J Geosci 8, 9373–9388 (2015). https://doi.org/10.1007/s12517-015-1850-3
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DOI: https://doi.org/10.1007/s12517-015-1850-3