Changes in Morphometric Meander Parameters and Prediction of Meander Channel Migration for the Alluvial Part of the Barak River
Authors
-
Department of Civil Engineering, National Institute of Technology, Silchar – 788 010
Wajahat Annayat -
Department of Civil Engineering, National Institute of Technology, Silchar – 788 010
Briti Sundar Sil
DOI:
https://doi.org/10.1007/s12594-020-1548-3Abstract
A common phenomenon associated with the alluvial river is its meandering action which leads to lateral migration and thus geomorphic hazards. Predicting and preventing this migration is both difficult and necessary. Barak river is one of the highly meandering rivers flowing through the alluvial plains of Assam, India. It is observed that there is a regular shifting of the river banks and development of cutoffs which create uncertainty to the people residing nearby. Therefore, in this study planform geometry and migration behaviour of the Barak river is examined considering 12 representative meandering reaches using multiperiod Landsat remote sensing images, field investigations of channel bed and bank properties and riparian vegetation cover. An attempt is made to describe and evaluate the empirical approach and time sequence extrapolation method to predict channel migration. Channel wavelength to channel width ratio ranges between 5.53 to 12.9, and the bend curvature ranges between 1.1 to 3.93. Rate of river migration varies between 0.54to 85.69 m/year. Sinuosity in most of the meandering reaches is greater than 1.5. Results show that lack of significant riparian vegetative cover, high precipitation and presence of fine sands with very low clay content are probably the main elements responsible for the planform changes. The results of the prediction of meander migration obtained from selected empirical methods show that only Nanson and Hickin method shows a moderate correlation with R2 =0.50. Time sequence extrapolation method was used to predict the radius of the best-fit circle for the year 2025 and 2030. Results of the time sequence extrapolation method indicate that the maximum and minimum radius of the best circle fit for the year 2025 is 1254m at reach-8 and 462m at reach-7 respectively, and maximum and minimum radius of the best circle fit for the year 2030 is 1319m at reach-8 and 387m at reach-12 respectively. It is believed that the outcomes of this study could form a base in river training works and in understanding and predicting the future dynamics and bank migration of this alluvial river and other river of similar geomorphic setting.
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Ahmed, A.A. and Fawzi, A. (2011) Meandering and bank erosion of the River Nile and its environmental impact on the area between Sohag and ElMinia, Egypt. Arabian Jour. Geosci., v.4, pp.1–11.
Bogoni, M., Putti, M. and Lanzoni, S. (2017) Modeling meander morphodynamics over self formed heterogeneous floodplains. Water Resour. Res., v.53(6), pp.5137–5157.
Choudhury, B.U., Fiyaz, A.R., Mohapatra, K.P. and Ngachan, S. (2016) Impact of land uses, agrophysical variables and altitudinal gradient on soil organic carbon concentration of north eastern Himalayan region of India. Land Degradation & Development, v.27(4), pp.1163–1174.
Choudhury, P. and Ullah, N. (2014) Downstream flow top width prediction in a river system. Water SA, v.40(3), pp.481–490.
Chu, Z.X., Sun, X.G., Zhai, S.K. and Xu, K.H. (2006) Changing pattern of accretion/erosion of the modern Yellow River (Huanghe) subaerial delta, China: Based on remote sensing images. Marine Geol., v.227(1–2), pp.13– 30.
Dar, R.A., Romshoo, S.A., Chandra, R. and Mir, I. (2014) ectono geomorphic study of Karewa basin of Kashmir Himalayas. Jour. Asian Earth Sci., v.____, pp.143–156.
Dar, R.A., Mir, S.A. and Romshoo, S.A. (2019) Influence of geomorphic and anthropogenic activities on channel morphology of River Jhelum in Kashmir Valley, NW Himalayas. Quaternary Internat., v.507, pp.333-341.
Das, J.D., Dutta, T. and Saraf, A.K. (2007) Remote sensing and GIS application in change detection of the Barak river channel, NE India. Jour. Indian Soc. Remote Sensing, v.35(4), pp.301–312.
De Rose, R.C. and Basher, L.R. (2011) Measurement of river bank and cliff erosion from sequential LIDAR and historical aerial photography. Geomorphology, v.126(1–2), pp.132–147.
Debnath, J., Pan, N. Das, Ahmed, I. and Bhowmik, M. (2017) Channel migration and its impact on land use/land cover using RS and GIS: A study on Khowai River of Tripura, North-East India. Egyptian Jour. Remote Sensing and Space Science, v.20(2), pp.197–210.
Dhari, S., Arya, D.S. and Murumkar, A.R. (2015) Application of remote sensing and GIS in sinuosity and river shifting analysis of the Ganges River in Uttarakhand plains. Applied Geomatics, v.7(1), pp.13–21.
Engel, F.L. and Rhoads, B.L. (2012) Interaction among mean flow, turbulence, bed morphology, bank failures and channel planform in an evolving compound meander loop. Geomorphology, v.163, pp.70–83.
Heitmuller, F.T., Hudson, P.F. and Kesel, R.H. (2017) Overbank sedimentation from the historic AD 2011 flood along the Lower Mississippi River, USA. Geology, v.45(2), pp.107–110.
Heo, J., Duc, T.A., Cho, H.-S. and Choi, S.-U. (2009) Characterization and prediction of meandering channel migration in the GIS environment: A case study of the Sabine River in the USA. Environ. Monit. Assess., v.152(1–4), pp.155.
Hooke. J.M. (1980) Magnitude and distribution of rates of river bank erosion. Earth Surface Process, v.5(2), pp.143-157, John Wiley, Chichester, NY.
Hooke, J.M. (1984) Changes in river meanders: a review of techniques and results of analyses. Progress in Physical Geography, v.8(4), pp.473–508.
Hooke, J.M. (2013) River meandering. In: Shroder, J. (Ed.), Wohl, E. (Ed.), Treatise on Geomorphology. Academic Press, San Diego, CA, v.9, Fluvial Geomorphology, pp.260–288. doi:10.1016/B978-0-12-374739-6.002414
Jain, S.K., Agarwal, P.K. and Singh, V. P. (2007) Hydrology and water resources of India (Vol. 57). Springer Science & Business Media.
Juyal, N., Sundriyal, Y., Rana, N., Chaudhary, S., Singhvi, A.K., (2010) Late Quaternary fluvial aggradation and incision in the monsoon dominated Alaknanda valley, Central Himalaya, Uttrakhand, India. Jour. Quaternary Sci., v.25(8), pp.1293–1304.
Mueller, J.E. (1968) An introduction to the hydraulic and topographic sinuosity indexes. Annals of the Association of American Geographers, v.58(2), pp.371–385.
Nanson, G.C. and Hickin, E.J. (1983) Channel migration and incision on the Beatton River. Jour. Hydraulic Engg., v.109(3), pp.327–337.
Nicoll, T.J. and Hickin, E.J. (2010) Planform geometry and channel migration of confined meandering rivers on the Canadian prairies. Geomorphology, v.116(1–2), pp.37–47.
Ollero, A. (2010) Channel changes and floodplain management in the meandering middle Ebro River, Spain. Geomorphology, v.117(3–4), pp.247–260.
Ray, Y. and Srivastava, P. (2010) Widespread aggradation in the mountainous catchment of the Alaknanda–Ganga River System: timescales and implications to Hinterland–foreland relationships. Quaternary Sci. Rev., v.29 (17–18), pp.2238–2260.
Romshoo, S.A., Altaf, S., Rashid, I. and Dar, R.A. (2018) Climatic, geomorphic and anthropogenic drivers of the 2014 extreme flooding in the Jhelum basin of Kashmir, India. Geomatics, Natural Hazards and Risk, v.9(1), pp.224-248.
Rousseau, Y.Y., Van de Wiel, M.J. and Biron, P.M. (2017) Simulating bank erosion over an extended natural sinuous river reach using a universal slope stability algorithm coupled with a morphodynamic model. Geomorphology, v.295, pp.690–704.
Rust, B.R. (1977) A classification of alluvial channel systems. In: Miall, A.D. (Ed.), Fluvial sedimentology. Canadian Society of Petroleum Geologists Memoir 5, Calgary, pp.187–198.
Schumm, S.A. (1986) Alluvial river response to active tectonics. Act. Tect., pp.80–94.
Schwenk, J. and Foufoula Georgiou, E. (2016) Meander cutoffs nonlocally accelerate upstream and downstream migration and channel widening. Geophys. Res. Lett., v.43(24), pp., pp.12,437–12,445. doi:10.1002/ 2016GL071670.
Spiekermann, R., Betts, H., Dymond, J. and Basher, L. (2017) Volumetric measurement of river bank erosion from sequential historical aerial photography. Geomorphology, v.296, pp.193–208.
Thakur, P.K., Laha, C. and Aggarwal, S.P. (2012) River bank erosion hazard study of river Ganga, upstream of Farakka barrage using remote sensing and GIS. Natural Hazards, v.61(3), pp.967–987.
Timár, G. (2003) Controls on channel sinuosity changes: a case study of the Tisza River, the Great Hungarian Plain. Quaternary Sci. Rev., v.22(20), pp.2199–2207.
Wellmeyer, J.L., Slattery, M.C. and Phillips, J.D. (2005) Quantifying downstream impacts of impoundment on flow regime and channel planform, lower Trinity River, Texas. Geomorphology, v.69(1–4), pp.1– 13.
Yang, X., Damen, M.C.J. and Van Zuidam, R.A. (1999) Satellite remote sensing and GIS for the analysis of channel migration changes in the active Yellow River Delta, China. Internat. Jour. Appl. Earth Observation and Geoinformation, v.1(2), pp.146–157.
Youdeowei, P.O. (1997) Bank collapse and erosion at the upper reaches of the Ekole creek in the Niger delta area of Nigeria. Bull. Engg. Geol. Environ., v.55(1), pp.167–172.
Yousefi, S., Moradi, H.R., Pourghasemi, H.R. and Khatami, R. (2017) Assessment of floodplain landuse and channel morphology within meandering reach of the Talar River in Iran using GIS and aerial photographs. Geocarto Internat., v.___, pp.1–14.
Yousefi, S., Pourghasemi, H.R., Hooke, J., Navratil, O. and Kidová, A. (2016) Changes in morphometric meander parameters identified on the Karoon River, Iran, using remote sensing data. Geomorphology, v.271, pp.55–64.
Zaimes, G.N., Schultz, R.C. and Isenhart, T.M. (2004) Stream bank erosion adjacent to riparian forest buffers, row-crop fields, and continuously-grazed pastures along Bear Creek in central Iowa. Jour. Soil and Water Conservation, v.59(1), pp.19–27
