Effect of Runoff Dynamic on Sediment and Nitrogen Losses in an Agricultural Watershed of the Southern Shaanxi Region, China

Liu, Quan; Li, Zhanbin; Li, Peng

doi:10.1002/clen.201200259

Cited by 8 publications

(5 citation statements)

References 39 publications

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“…The evaluated results (especially regressions after runoff separation), showed that the pollution coming from non‐point sources (including tile drainage systems) was relatively variable for all the monitored parameters and that the solute loads were influenced predominantly by hydrology. This is in agreement with findings from similar studies . The monthly specific solute loads for all monitored subcatchments, i.e.…”

Section: Resultssupporting

confidence: 93%

“…In general, all these phenomena depend on the ‘behaviour’ of various catchment segments in different phases of the year or during R–R events in relation to the natural, anthropogenic or ‘mixed’ factors . These factors are the weather course, land cover (land use and management, crop/tree, type and timing of agro‐technology/forest operation management), application of fertilizers, heterogeneous physical and chemical soil properties, geomorphological, hydrological and hydrogeological conditions of a watershed and land improvement interventions in various watershed zones .…”

Section: Introductionmentioning

confidence: 99%

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Quantifying Water Pollution Sources in a Small Tile‐drained Agricultural Watershed

Fučík

Hejduk

Peterková

2014

CLEAN Soil Air Water

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Research ArticleQuantifying Water Pollution Sources in a Small Tile-drained Agricultural Watershed This paper evaluates the quantity and quality dynamics of surface and drainage waters in a small, 7.1 km 2 agricultural watershed, located in the crystalline complex of the Czech Republic. Concentrations and monthly solute loads of amonium nitrogen (NH 4 -N), nitrate nitrogen (NO 3 -N), phosphate phosphorus (PO 4 -P) and total phosphorus (P tot ) from ten watershed's subcatchments with different soil, land use and tile drainage characteristics were compared for the period March-October from 2009 to 2011. The results and relevant processes were described using regular monitoring as well as event-based sampling approaches, methods of runoff separation and regression techniques. The average baseflow comprised 35-50%, whereas interflow and overland flow were 50-65% of the total runoff. The highest concentrations of NO 3 -N were detected in waters originating from cultivated and tiled subcatchments; those of NH 4 -N, PO 4 -P and P tot came from subcatchments containing settlements and water ponds. In the monitored sites within the watershed, non-point pollution sources produced on average 23% of NH 4 -N, approximately 45% of NO 3 -N, 24% of PO 4 -P and about 26% of P tot of total monthly solute loads. The differences in the share of monitored subcatchments in the total load from non-point pollution sources varied from month to month and were caused mainlybymiscellaneous hydrologicalconditionsand naturalaswellasman-alteredrunoff characteristics. The obtained results confirmed that used methods count for a useful approach for discerning water pollution sources and their dynamics in small, tile drained watersheds.

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Section: Resultssupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Quantifying Water Pollution Sources in a Small Tile‐drained Agricultural Watershed

Fučík

Hejduk

Peterková

2014

CLEAN Soil Air Water

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“…Runoff and vegetative ground cover were the main factors that were responsible for the differences in sediment and nitrogen losses . The runoff dynamics and stage of crop were the main responsible factors for sediment and nitrogen losses from agricultural watersheds . It can also be observed that for <50% grass coverage treatment, irrespective of the discharge, erosion started.…”

Section: Resultsmentioning

confidence: 94%

Effectiveness of Dichanthium annulatum in Watercourses for Reducing Sediment Delivery from Agricultural Watersheds

Rao

Mishra

Kurothe

et al. 2014

CLEAN Soil Air Water

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A field experiment was conducted to determine the efficacy of Dichantium annulatum grass filters in watercourses and to optimize the grass coverage in these watercourses. This experiment was conducted in 2% slope watercourses with varying filter grass coverage (0, 25, 50, 75, 100%) as main treatments and different flow rates (5, 10, 15, 20 L/s) as sub-treatments. The inflow and outflow, flow velocity, depth of the flow, and sediment concentration was measured and analyzed for each run. The experimental results reveal that the grass filter strips are able to reduce the sediment concentration in the runoff water by six times (from 4.2 to 0.65 g/L). The filter strips are able to reduce the velocity of the runoff water by two times (from 1.06 to 0.47 m/s) and convert the supercritical flows into subcritical flows. The filter strips are able to increase the Manning's coefficient from 0.0323 to 0.1006 under various discharges. From the experiment, it can be concluded that more than 50% grass filter coverage in watercourses did not further reduce sediment concentration, outflow, flow velocity, and the Froude number and increase roughness of the channels. Based on these results, it is recommended that D. annulatum can be used as a filter in watercourses to prevent runoff and soil losses from crop fields and thereby reducing the sedimentation of downstream water bodies. The optimum grass coverage, i.e. 50% of the channel length, can maintain the maximum grass production with minimum soil loss.

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“…If the return flow were to be reused, e.g. unused water in upstream area being reused in downstream area, redundant water diversion project and secondary investment would be required [15]. Considering the commodity value of irrigation water itself and economic connotation involved in management of irrigation water, we should maximize its one-time utilization rate and minimize the costs of secondary utilization [16].…”

Section: Connotation Of Irrigation Water Use Efficiencymentioning

confidence: 99%

Irrigation Water Use Efficiency Based on the Deficit Irrigation Theories

Jia

Zheng

2013

AMR

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Irrigation water use efficiency is an important index to evaluate agricultural water use efficiency of irrigation districts, and is a basic parameter of hydraulic engineering construction and water management. However, there are many problems in practical applications of the traditional irrigation water use efficiency which is based on sufficient irrigation theory. This paper puts forward a new concept and determination method of irrigation water use efficiency based on the theories of deficit irrigation. Finally, we discussed the connotations from the project characteristics, benefit characteristics, spatial scale and time scale characteristics.

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Effect of Runoff Dynamic on Sediment and Nitrogen Losses in an Agricultural Watershed of the Southern Shaanxi Region, China

Cited by 8 publications

References 39 publications

Quantifying Water Pollution Sources in a Small Tile‐drained Agricultural Watershed

Quantifying Water Pollution Sources in a Small Tile‐drained Agricultural Watershed

Effectiveness of Dichanthium annulatum in Watercourses for Reducing Sediment Delivery from Agricultural Watersheds

Irrigation Water Use Efficiency Based on the Deficit Irrigation Theories

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