Abstract
The present study aims to quantify the transfer of sediments and nutrients from an inter-montane agricultural catchment located in lower Himachal Himalayas of north western India. The study is based on long-term water quality data for July to September months for the period 2004 to 2010. The data for this study has been procured from Bhakra Beas Management Board, Sundernagar. The study has revealed a high degree of transfer and variability in sediment and nutrient concentrations, loads and yields, causing pollution downstream. The sediment concentrations have varied from 10 to 8117 mg/l with a variability of 54%. The micro nutrients concentrations have varied from 0.03 to 0.41 mg/l for zinc, 0.13 to 6.64 mg/l for iron and 0.02 to 1.30 mg/l for copper. Among the macro nutrients, highest concentrations have been observed for sulphate (11.81 mg/l) followed by phosphate (0.97 mg/l) and nitrate (0.40 mg/l). The correlation analysis has revealed that sediment and nutrient flux from the catchment are dependent on amount of stream flow. However, the extent of correlations has been, in general, low or non-significant. The findings of this study will have key implications for future sediment and nutrient transfer from agricultural catchments of north western Himalayan region.
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References
APHA (1998) Standard methods for examination of water and waste water. American Public Health Association, Washington DC.
Baumler, R., Zech, W. (1999) Effects of forest thinning on the stream water chemistry of two forest watersheds in the Bavarian Alps. Forest Ecology and Management, v.116, pp.119–128.
Beck, H.J., Birch, G.F. (2012) Metals, nutrients and total suspended solids discharged during different flow conditions in highly urbanized catchments. Environ Monit Assess., v.184, pp.637–653.
Bhat, S.A., Meraj, G., Pandit, A.K. (2016) Assessing the influence of stream flow and precipitation regimes on water quality of the major inflow stream of Wular Lake in Kashmir Himalaya. Arabian Jour. Geosci., v.9(50), pp.115.
Bond, T., Huang, J., Templeton, M.R., Graham, N. (2011) Occurrence and control of nitrogenous disinfection by products in drinking water: A review. Water Res., v.45, pp.4341–4354.
Bowes, M.J., Smith, J.T., Neal, C. (2009) The value of higher solution nutrient monitoring: A case study of the river Frome, Dorset, UK. Jour. Hydrol., v.378, pp.82–96.
Duncan, R.A., Bethune, M.G., Thayalakumaran, T., Christen, E.W., McMahon, T.A. (2008) Management of salt mobilisation in the irrigated landscape-A review of selected irrigation regions. Jour. Hydrol., v.351, pp.238–252.
Edwards, A.C., Withers, P.J.A. (2008) Transport and delivery of suspended solids, nitrogen and phosphorus from various sources to fresh waters in the UK. Jour. Hydrol., v.350, pp.144–153.
Ekholm, P., Kallio, K., Salo, S., Pietilainen, O.P., Rekolainen, S., Laine, Y. Joukola, M. (2000) Relationship between catchment characteristics and nutrient concentrations in an agricultural river system. Water Res., v.34, pp.3709–3716.
Fraterrigo, J.M., Downing, J.A. (2008) The influence of land use on lake nutrients varies with watershed transport capacity. Ecosystems, v.11, pp.1021–1034.
Garcia-Ruiz, J.M., Begueria, S., Nadal-Romero, E., Gonalez-Hidalgo, J.C., Lana-Renault, N., Sanjuan, Y. (2015) A meta-analysis of soil erosion rates across the world. Geomorphology, v.239, pp.160–173.
Gokbulak, F., Serengil, Y., Ozhan, S., Ozyuvaci, N., Balci, A.N. (2008) Relationship between streamflow and nutrient and sediment losses from an oak-beech forest watershed during an 18-year long monitoring study in Turkey. European Jour. Forest Res., v.127, pp.203–212.
Heathcote, A.J., Filstrup, C.T., Downing, J.A. (2013) Watershed sediment losses to lakes accelerating despite agricultural soil conservation efforts. PLOS ONE, v.8, pp. e53554.
Heejun, C. (2008) Spatial analysis of water quality trends in the Han River basin, South Korea. Water Res., v.42, pp. 3285–3304.
Hoyas, T.R., Vagstad, N., Bechmann, M., Eggestad, H.O. (1997) Nitrogen budget in the river Auli catchment: A catchment dominated by agriculture, in south eastern Norway. Ambio, v.26, pp. 289–295.
Isidoro, D., Quilez, D., Aragues, R. (2003) Sampling strategies for the estimation of salt and nitrate loads in irrigation return flows: La Violada Gully (Spain) as a case study. Jour. Hydrol., v.271, pp.39–51.
Jain, A., Rai, S.C., Sharma, E. (2000) Hydro-ecological analysis of a sacred lake watershed system in relation to land use/cover change from Sikkim Himalaya. Catena, v.40, pp.263–278.
Kennedy, C.D., Alverson, N., Jeranyama, P., DeMoranville, C. (2018) Seasonal dynamics of water and nutrient fluxes in an agricultural peatland. Hydrological Processes, v.32, pp.698–712.
Kothyari, B.P., Verma, P.K., Joshi, B.K., Kothyari, U.C. (2004). Rainfall-runoff-soil and nutrient loss relationships for plot size areas of Bhetagad watershed in Central Himalaya, India. Jour. Hydrol., v.293, pp. 137–150.
Lal, M., Mishra, S.M. (2015) Characterization of surface runoff, soil erosion, nutrient loss and their relationship for agricultural plots in India. Curr. World Environ., v.10(2), pp.593–601.
Lazaro-Vazuez, A., Castillo, M.M., Jarquim-Sanchez, A., Carrillo, L., Capps, K.A. (2018) Temporal changes in the hydrology and nutrient concentrations of a large tropical river: Anthropogenic influence in Lower Grijalva River, Mexico. River Res. Appli., v.34, pp.649–660.
Lee, S.W., Hwang, S.J., Lee, S.B., Hwang, H.S., Sung, H.C. (2009) Landscape ecological approach to the relationships of land use patterns in watersheds to water quality characteristics. Landscape and Urban Planning, v.92, pp.80–89.
Lian, Y., You, J.Y., Sparks, R., Demissie, M. (2012) Impact of human activities to hydrologic alterations on the Illinois River. Jour. Hydrol. Engg., v.17, pp.537–546.
McDowell, R., Trudgill, S. (2000) Variation of phosphorus loss from a small catchment in south Devon, UK. Agricultural Ecosys. Environ., v.79, pp.143–157.
Merchan, D., Casali, J., De Lersundi, D.V., Campo-Bescos, M.A., Gimenez, R., Preciado, B., Lafarga, A. (2018) Runoff, nutrients, sediment and salt yields in an irrigated watershed in southern Navarre (Spain). Agricultural Water Management, v.195, pp. 120–132.
Merchán, D., Causapé, J., Abrahão, R. (2013) Impact of irrigation implementation on hydrology and water quality in a small agricultural basin in Spain. Hydrol. Sci. Jour., v.58, pp.1400–1413.
Milliman, J.D., Meade, R.H. (1983) Worldwide delivery of river sediments to the oceans. Jour. Geol., v.91, pp.1–21.
Molder, B., Cockburn, J., Ber, A., Lindsay, J., Woodrow, K. (2015) Sediment assisted nutrient transfer from a small, no-till, tile drained watershed in south western Ontario, Canada. Agricultural Water Management, v.152, pp. 31–40.
Mukundan, R., Pradhanang, S.M., Schneiderman, E.M., Pierson, D.C., Anadhi, A., Zion, M.S., Matanse, A.H., Lounsbury, D.G., Steenhuis, T.S. (2013) Suspended sediment source areas and future climate impact on soil erosion and sediment yield in a New York City water supply watershed, USA. Geomorphology, v.183, pp.110–119.
Nakamura, F., Nakamura, T., Watanabe, O., Yamada, H., Nakagawa, Y., Kaneko, M. (2003) The current status of Kushiro Mire and an overview of restoration projects. Japanese Jour. Conserv. Ecol., v.8, pp.129–143.
Neal, C., Heathwaite, C.L. (2005) Nutrient mobility within river basins: A European perspective. Jour. Hydrol., v.304, pp.477–490.
Nie, X.F., Li, H.P., Jiang, J.H., Diao, Y.Q., Li, P.C. (2015) Spatiotemporal variation of riverine nutrients in a typical hilly watershed in southeast China using a multivariate statistics tool. Jour. Mountain Sci., v.12, pp. 983–998.
Pärn, J., Pinay, G., Mander, U. (2012) Indicators of nutrients transport from agricultural catchments under temperate climate: A review. Ecological Indicators, v.22, pp. 4–15.
Rai, S.C., Sharma, E. (1998a) Comparative assessment of runoff characteristics under different land use patterns within a Himalayan watershed. Hydrolog. Proces., v.12, pp. 2235–2248.
Rai, S.C., Sharma, E. (1998b) Hydrology and nutrient flux in an agrarian watershed of the Sikkim Himalaya. Jour. Soil and Water Conserv., v.53, pp.125–132.
Ramshoo, S.A., Muslim, M. (2011) Geospatial modelling for assessing the nutrient load of a Himalayan lake. Environ. Earth Sci., v.64, pp.1269–1282.
Rawat, J.S., Rai, S.P (1997) Pattern and intensity of erosion in the environmentally stressed Khulgad watershed, Kumaun Himalaya. Jour. Geol. Soci. India, v.50, pp. 331–338.
Rawat, J.S., and Rawat, M.S. (1994) Accelerated erosion and denudation in the Nanakosi watershed, Central Himalayas, India, Part I: sediment load. Mountain Research and Development, v.14, pp.25–38.
Reuss, Jo., Stottlemyer, R., Troendle, C.A. (1997) Effect of clear cutting on nutrient fluxes in a subalpine forest at Fraser, Colorado. Hydrol. Earth System Sci., v.1, pp.333–344.
Rodríguez-Blanco, M.L., Taboada-Castro, M.M., Taboada-Castro, M.T. (2013) Phosphorus transport into a stream draining from a mixed land use catchment in Galicia (NW Spain): Significance of runoff events. Jour. Hydrol., v.481, pp.12–21.
Schilling, K.E., Isenhart, T.M., Palmer, J.A., Wolter, C.F., Spooner, J. (2011) Impacts of land-cover change on suspended sediment transport in two agricultural watersheds. Jour. Amer. Water Resour. Assoc., v.47, pp.6720–686.
Sharma, E., Rai, S.C., Sharma, R. (2001) Soil, water and nutrient conservation in mountain farming system: Case study from the Sikkim Himalaya. Jour. Environ. Managmt., v.61, pp.123–135.
Sharma, P., Rai, S. (2004) Streamflow, sediment and carbon transport from a Himalayan watershed. Jour. Hydrol., v.289, pp.190–203.
Sileika, A.S., Gaigalis, K., Kutra, G., Smitiene, A. (2005) Factors affecting N and P losses from small catchments (Lithuania). Environ. Monit. Assess., v.102, pp. 59–374.
Silva, M.D.L., Souza, M.F.L., Silva, F.S., Paula, F.C.F., Moraes, M.E.B., Strenzel, G.M.R. (2015) Land use effects on nutrients concentration in a small watershed in northeast Brazil. Brazilian Jour. Aquatic Sci. Tech., v.19, pp.102–111.
Singh, O., Sharma, M.C., Sarangi, A., Singh, P. (2008) Spatial and temporal variability of sediment and dissolved loads from two alpine watersheds of the Lesser Himalayas. Catena, v.76, pp.27–35.
Singh, O., Singh, P., Sarangi, A., Sharma, M.C., Kumar, S. (2010) Anthropogenic impacts on the sediment flux in two alpine watersheds of the lesser Himalayas. Curr. Sci., v.99, pp.608–618.
Swank, W.T., Vose, J.M., Elliott, K.J. (2001) Long-term hydrologic and water quality responses following commercial clearcutting of mixed hardwoods on a southern Appalachian catchment. Forest Ecology and Management, v.143, pp.163–178.
Tang, J.L., Zhang, B., Gao, C., Zepp, H. (2008) Hydrological pathway and source area of nutrient losses identified by a multi-scale monitoring in an agricultural catchment. Catena, v.72, pp.374–385.
Tattari, S., Koskiaho, J., Kosunen, M., Lepisto, A., Linjama, J., Puustinen, M. (2017) Nutrient loads from agricultural and forested areas in Finland from 1981 up to 2010- can the efficiency of undertaken water protection measures seen? Environ. Monit. Assess., v.89, pp.95.
Toky, O.P., Ramakrishnan (1981) Run-off and infiltration losses related to shifting agriculture (jhum) in north-eastern India. Environ. Conserv., v.8, pp.313–321.
Vinten, A.J.A., Smith, K.A. (1993) Nitrogen cycling in agricultural soils. In: T.P. Burt, A.L. Heathwaite and S.T. Trudgill (Eds), Nitrate: Processes, Patterns and Management, Wiley, New York, pp.39–73.
Vitousek, P.M., Aber, J., Howarth, R.W., Likens, G.E., Matson, P.A., Schindler, D.W., Schlesinger, W.H., Tilman, G.D. (1997) Human alteration of the global nitrogen cycle: causes and consequences. Ecological Applications, v.7, pp.737–750.
Wang, X., Burns, D.A., Yanai, R.D., Briggs, R.D., Germain, R.H. (2006) Changes in stream chemistry and nutrient export following a partial harvest in the Catskill Mountains, New York, USA. Forest Ecology and Management, v.223, pp.103–112.
Wang, Y., Rhoads, B. L., Wang, D. (2016) Assessment of the flow regime alterations in the middle reach of the Yangtze River associated with dam construction: Potential ecological implications. Hydrolog. Proces., v.30, pp.3949–3966.
Webster, C.P., Belford, R.K., Cannel, R.P. (1986) Crop uptake and leaching losses of 15N- labelled fertilizer nitrogen in relation to waterlogging of clay and sandy loam soils. Plant Soil, v.92, pp.89–101.
Yue, Z., Lu, X.X., Ying, H., Yunmei, Z. (2004) Anthropogenic impacts on the sediment flux in the dry-hot valleys of Southwest China-an example of the Longchuan River. Jour. Mountain Sci., v.1, pp.239–249.
Yunus, A.J.M., Nakagoshi, N. (2004) Effects of seasonality on streamflow and water quality of the Pinang river in Penang island, Malaysia. Chinese Geograph. Sci., v.14, pp.153–161.
Acknowledgements
We would like to thank the authorities of Bhakra Beas Management Board, Sundernagar for providing the water quality data used in this study. We also thank the editor and the anonymous reviewer for his critical and constructive comments that have significantly improved this manuscript.
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Singh, J., Singh, O. Sediment and Nutrient Transfer from an Inter-montane Agricultural Catchment in Himachal Himalayas of Northwestern India. J Geol Soc India 97, 282–292 (2021). https://doi.org/10.1007/s12594-021-1679-1
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DOI: https://doi.org/10.1007/s12594-021-1679-1