Abstract
The Jamuna is one of the world’s most heavily sediment-laden braided river. Despite a major host for heavy mineral resources, the sediments of the Jamuna river are sparsely studied. A mineralogical and SEM-EDS investigation has been carried out in the middle part (along Sirajganj and Jamalpur district of Bangladesh) of the Jamuna river to appraise the grain size parameter, texture, depositional environment, heavy mineral distribution, and elemental composition of the heavy minerals. The results show that sediment samples are very fine to fine sand, moderate to well sorted, near symmetrical to strongly fine skewed, and mesokurtic to very leptokurtic. Uniform to graded suspension mechanisms are the processes for sediment deposition. Heavy minerals accumulation ranges from 0.5% to 9.33%, and the assemblages are predominantly marked by epidote, amphibole, followed by opaque (magnetite and ilmenite), garnet, zircon, sillimanite, apatite, tourmaline, rutile, kyanite, staurolite, monazite, chlorite, and titanite. The percentage of amphibole, garnet, and zircon decreases downstream and epidote increases in the same direction. The calculated zircon-tourmaline-rutile index (ZTR) varied between 3 to 13%, average apatite-tourmaline index (ATi), garnet-zircon index (GZi), rutile-zircon index (RuZi) and staurolite-zircon index (SZi) values are 54.55%, 75%, 38.68%, and 30% respectively. The Brahmaputra-Jamuna river sediments are derived from mixed-source regions (e.g., Shillong Plateau, Indo-Burman Ranges, and the Himalayas). The abundance of sub-angular to angular, high relief heavy mineral grains with sharp edges on the surface, conchoidal fractures, deep troughs, and breakage blocks infer that the provenance is close to the depositional area. The presence of rounded to sub-rounded, smoother surface with adhering particles, arcuate steps, and low to medium relief indicate the long-distance transportation of heavy mineral grains through fluvial environment.
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References
Abedin, M.J., Rahman, M.J.J., Sayem, A.S., and Abdullah, R. (2018) Heavy mineral distribution in sand deposits from the lower reaches of the Jamuna River, Bangladesh. Bangladesh Geosci. Jour., v.24, pp.1–15.
Ahmed, S.S., and Islam, M.B. (2001) Economic minerals in beach sands of the south eastern Bangladesh. Handbook of placer mineral deposits, pp.280-294.
Akon, E. (2019) Mineralogy, geochemistry and economic potentialities of heavy mineral sand resources of Bangladesh. Jour. Nepal Geol. Soc., v.59, pp.1–8.
Bae, W., Shim, H., Choi, D., Hwang, B., and Shin, E. (2002) Characteristics of contaminant release from lake sediment under different salinity and redox conditions. Geosci. Jour., v.6, pp.23–26.
Bristow, C.S. (1987) Brahmaputra River: Channel migration and deposition in: Ethridge, F.G., Flores, R.M., and Harvey, M.D. (Eds) Recent developments in fluvial sedimentology. Society of Economic Paleontologists and Mineralogists, v.39, pp.63-74.
Chowdhury, M.A. (1989) Petrography of the Sand Samples of the Brahmaputra-Jamuna River Bars. Geol. Surv. Bangladesh, v.5(5), pp.1–20.
Coleman, J.M. (1969) Brahmaputra River: Channel processes and sedimentation. Sediment. Geol., v.3(2/3), pp.129–239.
Datta, D.K., and Subramanian, V. (1997) Texture and mineralogy of sediments from the Ganges-Brahmaputra-Meghna river system in the Bengal Basin, Bangladesh and their environmental implications. Environ. Geol., v.30, pp.181–188.
Dung, N.T., Bac, B.H., and Van Anh, T.T. (2017) Distribution and reserve potential of titanium-zirconium heavy minerals in Quang an Area, Thua Thien Hue Province, Vietnam. In: International conference on geospatial technologies and earth resources, Springer, Cham., pp.326–339.
Flemming, B.W. (2007) The influence of grain-size analysis methods and sediment mixing on curve shapes and textural parameters: Implications for sediment trend analysis. Sediment. Geol., v.202, pp.425–435.
Folk, R.L., and Ward, W.C. (1957) Brazos River bar: A study in the significance of grain size parameters. Jour. Sediment. Petrol., v.27, pp.3–26.
Faulp, P., Pavlopoulos, A., and Migirons, G. (1998) On the provenance of flysch deposits in the External Hellenides of mainland Greece: results from heavy mineral studies. Geol. Magz., v.135, pp.421–442.
Galy, A., and France-Lanord, C. (2001) Higher erosion rates in the Himalaya geochemical constraints on riverine fluxes. Geology, v.29, pp.23–26.
Gandhi, M.S., and Raja, M. (2014) Heavy mineral distribution and geochemical studies of coastal sediments between Besant Nagar and Marakkanam, Tamil Nadu, India. Jour. Radiation Res. Appl. Sci., pp.1-13.
Garzanti, E., Vezzoli, G., Andò, S., France-Lanord, C., Singh, S.K., and Foster, G. (2004) Sand petrology and focused erosion in collision orogens: the Brahmaputra case. Earth Planet. Sci. Lett., v.220, pp.157–174.
Goswami, D.C. (1985) Brahmaputra River, Assam India: Physiography, Basin denudation, and channel aggradation. Water Resour. Res., v.21(7), pp.959–978.
Hasan, A.S.M.M., Hossain, I., Rahman, M.A., Rahman, M.S., Zaman, M.N., and Biswas, P.K. (2018) FEG-EPMA mapping and Fe-Ti oxide mineral chemistry of Brahmaputra River sediments in Bangladesh: provenance and petrogenetic implications. Arabian Jour. Geosci., v.11, pp.567.
Heroy, D.C., Kuehl, S.A., and Googbred, S.L. (2003) Mineralogy of the Ganges and Brahmaputra Rivers: implications for river switching and Late Quaternary climate change. Sediment. Geol., v.155, pp.343–359.
Islam, M.N. (2000) Braiding and channel morphodynamics: The Brahmaputra-Jamuna River, Bangladesh. Doctoral dissertation, The University of Hull, Imaging Services North, Boston Spa, Wetherby, West Yorkshire.
Islam, M.R., Begum, S.F., Yamaguchi, Y., and Ogawa, K. (1999) The Ganges and Brahmaputra rivers in Bangladesh: basin denudation and sedimentation. Hydrol. Process, v.13, pp.2907–2923.
Järvelill, J.I., Kallaste, T., Kleesment, A., Pajusaar, S., and Raukas, A. (2019) Provenance of heavy minerals in the Quaternary deposits of the Lemme outcrop, Estonia, based on optical microscopy, X-ray diffractometry and scanning electron microscope microanalysis. Estonian Jour. Earth Sci., v.68, pp.76–87.
Jasy, J.B., Rahman, M.J.J., and Yeasmin, R. (2010) Sand petrology of the exposed bar deposits of the Brahmaputra-Jamuna River, Bangladesh: implications for provenance. Bangladesh Geosci. Jour., v.16, pp.1–22.
Jia, X., Wang, H., and Wan, H. (2014) Sources and trace element geochemical characteristics of the coarse sediment in the Ningxia Inner Mongolia reaches of the Yellow River. Geosci. Jour., v.18, pp.181–192.
Kim, J.G., Ko, K., Kim, T.H., Lee, G.H., Song, Y., Chon, C., and Lee, J. (2007) Effect of mining and geology on the chemistry of stream water and sediment in a small watershed. Geosci. Jour., v.11, pp.175–183.
Lahijani, H., and Tavakoli, V. (2012) Identifying provenance of South Caspian coastal sediments using mineral distribution pattern. Quaternary Internat., v.261, pp.128–137.
Lario, J., Spencer, C., Plater, A.J., Zazo, C., Goy, J.L., and Dabrio, C.J. (2002) Particle Size Characterization of Holocene back-barrier sequences from North Atlantic Coast (SW Spain and SE England). Geomorphology, v.42(1), pp.25–42.
Mahaney, W.C., and Kalm, V. (2000) Comparative SEM study of oriented till blocks, glacial grains and Devonian sands in Estonia and Latvia. Boreas, v.29, pp.35–51.
Mange, M.A., and Maurer, H.F.W. (1992) Heavy Minerals in Color. Chapman and Hall, London, pp.133.
Mange, M.A., and Wright, D.T. (2007) Heavy minerals in use. Developments in Sedimentology, v.58, pp.1328.
Milliman, J.D., and Syvitski, P.M. (1992) Geomorphic/tectonic control of sediment discharge to the ocean: the importance of small mountainous rivers. Jour. Geol., v.100(5), pp.525–544.
Mineral Commodity Summaries (2020) USGS. United States Government Printing Office, Washington.
Morton, A.C., and Hallsworth, C.R. (1994) Identifying provenance specific features of detrital heavy mineral assemblages in sandstones. Sediment. Geol., v.90, pp.241–256.
Passega, R. (1964) Grain size representation by CM patterns as a geological tool. Journal of Sedimentary Petrology, v.34, pp.830–847.
Pecher, A. (1989) The metamorphism in the Central Himalaya. Jour. Metamorp. Geol., v.7, pp.31–41.
Rahman, M.A., Biswas, P.K., Zaman, M.N., Miah, M.Y., Hossain, T., and Imamul Huq, S.M. (2012) Characterization of the sand of Brahmaputra river of Bangladesh. Bangladesh Jour. Scientiûc and Industrial Res., v.47, pp.167–172.
Rahman, M.A., Pownceby, M.I., Haque, N., Bruckard, W.J., and Zaman, M.N. (2014) Characterization of titanium-rich heavy mineral concentrates from the Brahmaputra River basin, Bangladesh. Trans. Instit. Min. Metall. B, v.123, pp.222–233.
Rahman, M.A., Pownceby, M.I., Haque, N., Bruckard, W.J., and Zaman, M.N. (2016) Valuable heavy minerals from the Brahmaputra River sands of Northern Bangladesh. Applied Earth Science (Trans. Inst. Min. Metall. B), v.125(3), pp.174–188.
Rahman, M.J.J., Pownceby, M.I., and Rana, M.S. (2020) Occurrence and distribution of valuable heavy minerals in sand deposits of the Jamuna River, Bangladesh. Ore Geol. Rev., 116.
Rajib, M., Moniruzzaman, M., and Oguchi, C.T. (2016) Economic minerals in fluvial bar sediment of Jamuna River, Bangladesh: geomorphic inference for prospecting rare earth oxides. Transactions, Japanese Geomorphological Union, v.37(3), pp.363–377.
Reyneke, L., and Van Der Westhuizen, W. G. (2001) Characterisation of a heavy mineral-bearing sample from India and the relevance of intrinsic mineralogical features to mineral beneficiation. Minerals Engineering, v.14(12), pp.1589–1600.
Shahr El-Din, A.M., Borai, E.H., and Abd El-Ghany, M.S. (2018) Selective separation of thorium from rare earth elements liquor during the alkaline processing of Egyptian monazite concentrate. Main Group Chem, v.17(1), pp.79–88.
Singh, S.K., and France-Lanord, C. (2002) Tracing the distribution of erosion in the Brahmaputra watershed from isotopic compositions of stream sediments. Earth Planet. Sci. Lett., v.202, pp.645–662.
Uddin, A., and Lundberg, N. (1998) Unroofing history of the eastern Himalaya and the Indo-Burman ranges: heavy-mineral study of Cenozoic sediments from the Bengal Basin, Bangladesh. Jour. Sediment. Res., v.68, pp.465–472.
Umitsu, M. (1987) Late Quaternary sedimentary environment and landform evolution in the Bengal lowland. Geographical Rev. Japan, v.60, pp.164–178.
Von Eynatten, H., and Dunkl, I. (2012) Assessing the sediment factory: The role of single grain analysis. Earth Sci. Rev., v.115, pp.97–120.
Voncken, J.H.L. (2016) The ore minerals and major ore deposits of the rare earths. In: Voncken, J. (ed.): The rare earth elements. Springer International Publishing, pp.15-52.
Yokoyama, K., Amano, K., Taira, A., and Satio, Y. (1990) Mineralogy of silts from the Bengal Fan, In: Cochran, J.R., Stow, D.A.V., et al., (eds.), Proceed of the Ocean Drilling Program. Scientific Results, Collede Station, Texas, v.116, pp.59-73.
Zaman, M.N., Rahman, M.A., and Biswas, P.K. (2012) Sands of the Brahmaputra River Basin: Identification of Valuable Heavy Minerals (VHM) in the sands of the Brahmaputra river. Lap Lambert Academic Publishing, pp.21-34.
Acknowledgements
The authors acknowledge the financial support from the University Grant Commission (UGC) of Bangladesh for this research. We express our gratitude to the laboratory technicians of the Department of Geological Sciences, Jahangirnagar University, Bangladesh, for their assistance. We are indebted to Dr. Moyra Wilson, School of Earth Science, University of Western Australia for her assistance in SEM studies and Sandy Lam, Microanalysis Australia, Perth for the SEM-EDS analysis. We thank the editor and anonymous reviewers for their reviews, constructive comments, and suggestions on the manuscript.
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Hossain, M.S., Aziz, M.T., Shahriar, M.S. et al. Heavy Mineral Analysis of Jamuna River Sediments, Bangladesh. J Geol Soc India 97, 470–480 (2021). https://doi.org/10.1007/s12594-021-1713-3
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DOI: https://doi.org/10.1007/s12594-021-1713-3