Contribution to the physico-chemical condition of granitoid emplacement in a part of Karbi Hills, NE India

Volume 1, Issue 2, December 2016     |     PP. 50-77      |     PDF (1978 K)    |     Pub. Date: December 27, 2016
DOI:    352 Downloads     8191 Views  

Author(s)

Dilip Majumdar, Department of Applied Geology, Dibrugarh University
Pankhi Dutta, Department of Applied Geology, Dibrugarh University
Abhijit Gogoi, Department of Applied Geology, Dibrugarh University

Abstract
Late Pan-African A-type, within plate, anorogenic granitoids dominate the lithology of the magmatic complex of northwest Karbi Hills, NE India. Petrographic analysis of these granitoids indicate enrichment of rare earth bearing accessory minerals like allanite, titanite, zircon, xenotime and monazite, constituting about 5% of total mineralogy, with concomitant rise in REE content (up to 2202.50 ppm; av.614.64 ppm), especially LREE. There are at least two episodes of textural modifications; the former are coarser, show crenulated crystal boundary with occasional interpenetrative grain structure; feldspars suffer extensive saussuritization and sericitization; biotite and plagioclases are studded with many volatile phases, viz., apatite, zircon etc. Quartz of latter generation are mostly fine grained, spherical, grown in a process of reducing surface or interfacial free energy during post magmatic recrystallization episode and production of microcline perthite. In our present study, mineralogical identifications have been done by optical microscopy and X-ray diffraction; physico-chemical status of study granitoids have been evaluated based on comprehensive EPMA analysis of constituent biotite, plagioclase and potash feldspar. The crystallization temperature extracted from EPMA of biotites suggests low emplacement temperature <700OC and pressure 1.65 -2.56 kb, corresponding to a depth of crystallization from 6.36-9.86 km. The plot of ∑FeO/∑(FeO+MgO) vs. % MgO, oscillating zoning in constituent zircons and Hf (t) of zircon (-12.20 to-18.90), refer to the derivation of magma from an older magmatic crust.

Keywords
Karbi Hills, Pan-African magmatism, EPMA, rare earth elements

Cite this paper
Dilip Majumdar, Pankhi Dutta, Abhijit Gogoi, Contribution to the physico-chemical condition of granitoid emplacement in a part of Karbi Hills, NE India , SCIREA Journal of Geosciences. Volume 1, Issue 2, December 2016 | PP. 50-77.

References

[ 1 ] Barooah, BC, Barman, SK, Goswami, ID (1983) Structural evolution of quartzite- greenstone terrane: Precambrian crystalline complex between Dizo Valley and Rengbengjuri, Assam, India, Ann. Jour. of the Geol. and Mining Serv. Assoc. Assam 2: 10-16.
[ 2 ] Beane, RE (1974) Biotite stability in the porphyry copper environment. Economic Geology 69: 241-256
[ 3 ] Bonin, B (2007) A-type granites and related rocks: Evolution of a concept, problems and prospects. Lithos 97: 1-29
[ 4 ] Bowden, P (1985) The geochemistry and mineralization of alkaline ring complexes in Africa (a review). Journal of African Sciences 3: 17-39
[ 5 ] Brown, M (2013) Granite: From genesis to emplacement. gsabulletin.gsapubs.org. v. 125; no. 7/8: 1079–1113; doi: 10.1130/B30877.1
[ 6 ] Chapman, RW, Williams, CR (1935) Evolution of the White Mountain Magma Series. American Mineralogist 20: 202-530
[ 7 ] Cullers, RL, Graf, JL (1984) Rare earth elements in igneous rocks of the continental crust: intermediate and silicic rocks — ore petrogenesis. In Henderson, P. (Editor) Rare Earth Element Geochemistry. Elsevier, Amsterdam, 275-316
[ 8 ] Deer, WA, Howie, RA, Zussman, J (1992) An introduction to the rock forming minerals. 2nd Editions, Longman Scientific and Technical, London 696
[ 9 ] Desikachar, S. V. (1974) A review of the tectonic and geological history of eastern India in terms of plate tectonic theory. Jour Geol. Soc. India, 15, 137–149.
[ 10 ] Evans, P. (1964) The tectonic framework of Assam. Jour Geol. Soc. India, 5, 80–96
[ 11 ] Etuso, U, Sho, E, Mitsutoshi, M (2007). Relationship between solidification depth of granitic rocks and formation of hydrothermal ore deposits. Resource Geology 57 (1): 47-56
[ 12 ] Foster, MD (1960) Interpretation of the Composition of TriocTahedral Micas. US Geological Survey, Professional Paper 354B: 11-49
[ 13 ] Gromet, L. Peter and Silver, Leon T. (1983) Rare earth element distributions among minerals in a granodiorite and their petrogenetic implications. Geochimica et Cosmochimica Acta, 47 (5). pp. 925-939.
[ 14 ] Haskin, LA, Schmitt, RA, (1967) Rare-earth distributions. Researches in geochemistry 2: 235-258
[ 15 ] Henry, DJ, Guidittic, CV, Thomson, JA (2005) The Ti-saturation surface for low-to-medium pressure metapeliticbiotite: Implications for geothermometry and Ti-substitution mechanisms. Journal of American Mineralogist 90: 316-328
[ 16 ] Hussain, M, Ahmed, T (2009) Geochemicalcharacterstics of the granitoids of Mikir Hills massif of Shillong Plateau, Northeast India: Implication of Pan- African magmatic activity. In Geological Anatomy of India and the Middle East (edsTalat Ahmed, Francis Hirsch and Punya Charusiri, J. Virtual Explor. El. Edn., paper 4
[ 17 ] Lindholm, R (1987) A Practical Approach to Sedimentology. Allen & Unwin, London: 136-153
[ 18 ] Majumdar, D, Dutta, P (2014) Rare earth element abundances in some A-type Pan- African granitoids of Karbi Hills, North East India. Curr. Sci. 107 (12): 2023– 2029
[ 19 ] Majumdar, D, Dutta, P (2016) Geodynamic evolution of a Pan-African granitoid of extended Dizo Valley in Karbi Hills, NE India: Evidence from Geochemistry and Isotope Geology. Journal of Asian Earth Sciences 117: 256–268
[ 20 ] Nachit, H, Razafimahefa, N, Stussi, JM, Caron, JP (1985) Composition chimique des Biotitesettypologiemagmatique des granitoids. C.R. Acadomic Sciences Paris, Series2, 301: 813-818
[ 21 ] Nakamura, N, (1974) Determination of REE, Ba, Fe, Mg, Na and K in carbonaceous and ordinary chondrites.Geochim.Cosmochim.Acta. 38: 757-775
[ 22 ] O’onins, RK, Pankhurst, RJ, (1974) Rare-earth element distribution in Archaean gneisses and anorthosites. Gothab area, West Greenland. Earth Planetary Sc. Lett. 22: 328-338
[ 23 ] Philbert, J, Tixier, R (1968) Electron penetration and atomic number correction in electron probe microanalysis. British journal of Applied Physics 1: 685-694
[ 24 ] Rajaraman, HS, Prakash, BG, Zakaulla, S, Umamaheswar, K, (2008) Petrography and geochemistry of the intrusive granites in the Shillong Basin of Mikir Hills, Assam. In: Proceedings of the National Seminar on Geology and Energy Resources of NE India: Progress and Perspectives Nagaland University Research Journal, Special Publication, pp 51–58 (ISSN 0973-0346)
[ 25 ] Reed, SJB (1993) Electron Microprobe Analysis, Cambridge University Press. 157
[ 26 ] Sanematsu, K, Ejima, T, Kon, Y, Manaka, T, Zaw, K, Morita,S, Seo, Y (2016) Fractination of rare-earth elements during magmatic differentiation and weathering of calc-alkaline granites in southern Myanmar. Mineralogical Magazine 80 (1): 77-102
[ 27 ] Streckeisen, AL (1973) Plutonic rocks, classification and nomenclature recommended by the IUGS subcommission on the systematic of igneous rocks. Geotimes, 18: 26-30.
[ 28 ] Wintsch RP, Christoffersen, R, Kronenberg, AK (1995) Fluid-rock reaction weakening of fault zones. Jour. Geoph. Res. 100: 13021-13032
[ 29 ] Zheng, Yong-Fei, Zhang, Shao-Bing, Zhao, Zi-Fu, Wu, Yuan-Bao, Li, Xianhua, Li, Zhengxiang, Wu, Fu-Yuan (2007) Contrasting zircon Hf and O isotopes in the two episodes of Neoproterozoicgranitoids in South China: implications for growth and reworking of continental crust. Lithos 96: 127–150
[ 30 ] Zhou, ZX, (1986) The origin of intrusive mass in Fengshandong, Hubei province. ActaPetrologicaSinica 2, 2: 59-70