Abstract
One of the major geomorphic processes that have assumed significance and turned into a quasi-natural hazard in the Anthropocene is soil erosion. Apart from the loss of millions of hectares of cultivable land, this sub-aerial process is associated with increased sediment load of rivers, thereby causing rapid siltation. Since the process of actual measurement of erosion is quite complex, geomorphologists have been dependent on prediction-based empirical models for ascertaining the erosion susceptibility. However, in humid areas of the globe, running water contributes most to the process of erosion. This is very much dependent on the channelized flow, which, in turn depends on the channel cross-section and fluvial hydraulic parameters. It has been found that in spite of greater probability of the erosion conditioning factors, the removal of top soil by the rivers is often subdued because of unfavourable hydraulic factors. So, the process of interlinking the predicted soil loss with the fluvial hydraulic parameters becomes significant in this realm. This study has, therefore, tried to correlate the RUSLE-based empirical erosion model with the fluvial hydraulic parameters of bankfull discharge, shear stress and unit stream power. Analysis reveals that a moderate positive correlation exists between them (r = 0.48–0.502). The moderately positive correlation between these factors suggests the fact that in areas where the erosion is higher, there is more possibility of elevated values of the hydraulic attributes. In other words, it implies that the fluvial hydraulic parameters help in augmenting the impact of erosion and removal of the top soil in this area to some extent. This is especially true in the middle domain of this basin in the vicinity of the Massanjore Dam on the Mayurakshi River. This is expected to contribute in enhancing the speed of sedimentation of the dam besides reducing the soil fertility and crop productivity in the entire area. In the lower domain also, it was observed that above tolerance soil loss is prevalent in most of the areas. Efficient conservation techniques such as agro-forestry in the upper and middle domains as well as straw mulching in the lower domain are the need of the hour to prevent further deterioration.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Data availability
Not Applicable.
Code availability
Not Applicable.
References
Andrews, E. D. (1980). Effective and bankfull discharge of stream in the Yampa River Basin, Colorado and Wyoming. Journal of Hydrology, 46, 311–330.
Arnoldus, H. M. J. (1980). An approximation of the factor in the universal soil loss equation. In M. De Boodt & D. Gabriels (Eds.), Assessment of erosion (pp. 127–132) Chichester, UK: John Wiley & Sons Limited.
Baker, V. R. (1973). Erosional form sand processes for the catastrophic Pleistocene Missoula flood sin eastern Washington. In M. Morisawa (Ed.), Fluvial geomorphology: Proceeding so the fourth annual geomorphology symposium (pp. 123–148). State University of New York.
Baker, V. R. (1978). Large-scale erosion landed positional features of Channel Scabland. In V. R. Baker & D. Nummedal (Eds.), The channelled scabland (p. 81). NASA.
Baker, V. R. (1988). Flood erosion. In V. R. Baker, R. C. Kochel, & P. C. Patton (Eds.), Flood geomorphology (pp. 81–95). Wiley.
Baker, V. R., & Costa, J. E. (1987). Flood. In L. Mayer & D. Nash (Eds.), Catastrophic flooding (pp. 1–21). Allen and Unwin.
Baker, V. R., & Ritter, D. F. (1975). Competence of rivers to transport coarse bedload material. Geological Society of America Bulletin, 86(7), 975–978.
Balasubramani, K., Veena, M., Kumaraswamy, K., & Saravanabavan, V. (2015). Estimation of soil erosion in a semi-arid watershed of Tamil Nadu (India) using revised universal soil loss equation (rusle) model through GIS. Modeling Earth Systems and Environment, 1, 1–17.
Bizzi, S., & Lerner, N. D. (2015). The use of stream power as an indicator of channel sensitivity to erosion and deposition processes. River Research and Applications River Research, 31, 16–27.
Buchanan, T. J., & Someres, W. P. (1969). Discharge measurements at gaging ststion: U.S. geological survey techniques of water resource investigation. Book 3, Chapter A8, pp. 1.
Burbank, D. W., Leland, J., Fielding, E., Anderson, R. S., Brozovic, N., Reid, M. R., & Duncan, C. (1996). Bedrock incision, rock uplift and threshold hillslopes in the northwestern Himalayas. Nature, 379, 505–510.
David, W. P. (1988). Soil and water conservation planning: Policy issues and recommendations. Phillipine Journal of Development, 15, 47–87.
Dhar, O. N., & Nandargi, S. (1995). On some characteristics of severe rainstorms of India. Theoretical and Applied Climatology, 50, 205–212.
Eekhout, J. P., & de Vente, J. (2022). Global impact of climate change on soil erosion and potential for adaptation through soil conservation. Earth-Science Reviews, 226, 103921. https://doi.org/10.1016/j.earscirev.2022.103921
FAO. (2017). Voluntary guidelines for sustainable soil management (p. 26). Food and Agriculture Organization of the United Nations.
Finnegan, J. N., Roe, G., Montgomert, R. D., & Halle, B. (2005). Controls on the channel width of rivers: Implications for modelling fluvial incision of bedrock. Geological Society of America Geology, 33, 229–232.
H.E.C. (1976). HEC-6: Scour and deposition in rivers and reservoirs: user’smanual. Hydrologic Engineering Centre. US Army Corps of Engineers.Computer Program 723-G2-L2470, California.
Islam, A., & DebBarman, S. (2020). Drainage basin morphometry and evaluating its role on flood-inducing capacity of tributary basins of Mayurakshi River, India. SN Applied Sciences, 2, 1087. https://doi.org/10.1007/s42452-020-2839-4
Kader, M. A., Singha, A., Begum, M. A., Jewel, A., Khan, F. H., & Khan, N. I. (2019). Mulching as water-saving technique in dryland agriculture. Bulletin of the National Research Centre, 43, 147. https://doi.org/10.1186/s42269-019-0186-7
Kale, V. S., & Hire, P. S. (2007). Temporal variations in the specific stream power and total energy expenditure of a monsoonal river: The Tapi River, India. Geomorphology, 92, 134–146.
Kale, V. S., Sengupta, S., Achyuthan, H., & Jaiswal, M. K. (2014). Tectonic controls upon Kaveri River drainage, cratonic Peninsular India: Inferences from longitudinal profiles, morphotectonic indices, hanging valleys and fluvial records. Geomorphology, 227, 153–165. https://doi.org/10.1016/j.geomorph.2013.07.027
Langendoen, E. J. (2008). Modeling the evolution of incised streams: Model formulation and validation of flow and streambed evolution components. Journal of Hydraulic Engineering, 134, 749–762.
Leliavsky, S. (1966). An introduction to fluvial hydraulics (p. 257). Dover Publication.
Masroor, M., Sajjad, H., Rehman, S., Singh, R., Rahaman, M. H., Sahana, M., Ahmed, R., & Avtar, R. (2022). Analysing the relationship between drought and soil erosion using vegetation health index and RUSLE models in Godavari middle sub-basin, India. Geoscience Frontiers, 13(2), 101312. https://doi.org/10.1016/j.gsf.2021.101312
Mitchell, T. D., Hulme, M., & New, M. (2002). Climate data for political areas. Area, 34, 109–112.
Moore, I. D., & Burch, G. J. (1986a). Modelling erosion and deposition: Topographic effects. Transactions of the ASAE, 29(6), 1624–1630.
Moore, I. D., & Burch, G. J. (1986b). Physical basis of the length slope factor in the universal soil loss equation. Soil Science Society of America Journal, 50(5), 1294–1298.
Montgomery, D. R. (2007). Soil erosion and agricultural sustainability. Proceedings of the National Academy of Science of the USA, 104, 13268–13272.
Mueller, L., Eulenstein, F., Mirschel, W., & Schindler, U. (2021). Optimizing agricultural landscapes: Measures towards prosperity and sustainability. Exploring and Optimizing Agricultural Landscapes, pp. 91–130. https://doi.org/10.1007/978-3-030-67448-93.
Neverman, A. J., Donovan, M., Smith, H. G., Ausseil, A. G., & Zammit, C. (2023). Climate change impacts on erosion and suspended sediment loads in New Zealand. Geomorphology, 427, 108607. https://doi.org/10.1016/j.geomorph.2023.10860
Olsen, N. R. B. (2003). Three-dimensional CFD modelling of self-forming meandering channel. Journal of Hydraulic Engineering, 129, 366–372.
Prosdocimi, M., Tarolli, P., & Cerda, A. (2016). Mulching practices for reducing soil water erosion: A review. Earth Science Reviews, 161(191), 203.
Renard, K. G., Foster, G. R., Weesies, G. A., McCool, D. K., & Yoder, D. C. (1997). Predicting soil erosion by water: a guide to conservation planning with the revised universal soil loss equation (RUSLE). Agriculture Handbook No. 703, USDA, Washington DC.
Rinaldi, M., Simoncini, C., & Piegay, H. (2009). Scientific design strategy for promoting sustainable sediment management: The case of the Magra River (Central-Northern Italy). River Research and Applications, 25, 607–625.
Roy, S., Das, S., & Sengupta, S. (2022a). Predicting terrain erosion susceptibility from drainage basin morphometry using ALOS-PALSAR DEM: Analysis from PCA-weighted AHP approach in a river system of eastern India. Environment, Development and Sustainability, 25, 9589–9617. https://doi.org/10.1007/s10668-022-02450-z
Roy, S., Das, S., Sengupta, S., Mistry, S., & Chatterjee, J. (2022b). Monitoring the temporal dimension of soil erosion in Mayurakshi Basin, India: A novel approach integrating RUSLE, Shannon’s entropy and landscape ecological metrics. Journal of Earth System Science, 131, 249. https://doi.org/10.1007/s12040-022-02006-9
Schumm, S. A. (1977). The fluvial system. Wiley.
Shepherd, R. G., & Schumm, S. A. (1974). An experimental study of river incision. Geological Society of America Bulletin, 85, 257–268.
Shields, F. D., Jr., Copeland, R. R., Klingeman, P. C., Doyle, M. W., & Simon, A. (2003). Design for stream restoration. Journal of Hydraulic Engineering, 129(8), 575–584.
Spalevic, V., Barovic, G., Vujacic, D., Curovic, M., Behzadfar, M., Djurovic, N., Dudic, B., & Billi, P. (2020). The impact of landuse changes on soil erosion in the river basin of Miocki Potok, Montenegro. Water, 12(11), 2973. https://doi.org/10.3390/w12112973
Sridhar, A., Laskar, A., Prasad, V., Sharma, A., Tripathi, J. K., Balaji, D., Maurya, D. M., & Chamyal, L. S. (2015). Late Holocene flooding history of a tropical river in western India in response to southwest monsoon fluctuations: A multi-proxy study from Lower Narmada Valley. Quaternary International, 371, 181–190.
Surian, N., & Rinaldi, M. (2003). Morphological response to river engineering and management in alluvial channels in Italy. Geomorphology, 50, 307–326.
Tetford, P. E., Desloges, J. R., & Nakassis, D. (2017). Modelling surface geomorphic processes using the RUSLE and specific stream power in a GIS framework, NE Peloponnese, Greece. Modeling Earth Systems and Environment, 3, 1229–1244. https://doi.org/10.1007/s40808-017-0391-z
Thomas, J., Joseph, S., Thrivikramji, K., Abe, G., & Kannan, N. (2009). Morphometrical analysis of two tropical mountain river basins of contrasting environmental settings, the southern Western Ghats, India. Environmental Earth Sciences, 66(8), 2353–2366. https://doi.org/10.1007/s12665-011-1457-2
Wallerstein, N. P., Soar, P. J., & Thorne, C. R. (2006). River energy auditing scheme (REAS) for catchment flood management planning. In International conference on fluvial hydraulics, Lisbon Portugal, pp. 1923–1932.
Wischmeier, W. H., & Smith, D. D. (1978). Predicting rainfall erosion losses: a guide to conservation planning. Agriculture Handbook No. 537, USDA, Washington, DC.
Wohl, E. E. (1992). Bedrock benches and boulder bars: Floods in the Burdekin Gorge of Australia. Geological Society of America Bulletin, 104, 770–778.
Wohl, E. (2000). Substrate influences on step-pool sequences in the Christopher Creek drainage, Arizona. The Journal of Geology, 108, 121–129.
Wohl, E. E., & Ikeda, H. (1998). Patterns of bedrock channel erosion on the Boso Peninsula, Japan. The Journal of Geology, 106, 331–345.
Wohl, E., & Legleiter, C. J. (2003). Controls on pool characteristics along a resistant boundary channel. The Journal of Geology, 111, 103–114.
Wu, B., Wang, G., Xia, J., Fu, X., & Zhang, Y. (2008). Response of bankfull discharge to discharge and sediment load in the lower yellow river. Geomorphology, 100, 366–376.
Yu, Y. Y., Turner, N. C., Gong, Y. H., Li, F. M., Fang, C., Ge, L. J., & Ye, J. S. (2018). Benefits and limitations to straw- and plastic-film mulch on maize yield and water use efficiency: A meta-analysis across hydrothermal gradients. European Journal of Agronomy, 99, 138–147.
Acknowledgements
The authors would like to acknowledge the financial support received from the Government of West Bengal, India (Swami Vivekananda Merit-Cum Means Scholarship). Acknowledgments are also due to the Editor-in-chief Luc Hens and two anonymous reviewers for sparing their valuable time in furnishing constructive suggestions which improved the content of this paper.
Funding
This research has not been funded by any organization. However, financial help in the form of fellowship (Swami Vivekananda Merit-Cum Means Scholarship) from the Government of West Bengal has been received by the 1st author.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no known issues of conflicting interest in the institutional and personal domain that may have played a part in influencing the work related to this paper.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Roy, S., Das, S., Chatterjee, J. et al. Interlinking erosion susceptibility, channel geometry and stream power: a case study of the Mayurakshi River, eastern India. Environ Dev Sustain (2024). https://doi.org/10.1007/s10668-024-04634-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10668-024-04634-1