Title: | An integrated methodology to analyze the total nitrogen accumulation in a drinking water reservoir based on the SWAT model driven by CMADS: A case study of the Biliuhe Reservoir in northeast China |
Authors: | Qin G., J. Liu, T. Wang, S. Xu and G. Su |
Year: | 2018 |
Journal: | Water |
Volume (Issue): | 10(11) |
Pages: | |
Article ID: | 1535 |
DOI: | 10.3390/w10111535 |
URL (non-DOI journals): | |
Model: | SWAT |
Broad Application Category: | hydrologic and pollutant |
Primary Application Category: | nitrogen cycling/loss and transport |
Secondary Application Category: | hydrologic assessment |
Watershed Description: | Combined 2,085 km^2 drainage area of the Biliuhe, Geli and Bajia Rivers, which drain to the Biliuhe Reservoir and is located northeast of the metropolitan area of Dalian in northeast China. |
Calibration Summary: | |
Validation Summary: | |
General Comments: | |
Abstract: | Human activities, especially dam construction, have changed the nutrient cycle process
at the basin scale. Reservoirs often act as a sink in the basin and more nutrients are retained
due to sedimentation, which induces the eutrophication of the surface water system. This paper
proposes an integrated methodology to analyze the total nitrogen (TN) accumulation in a drinking
water reservoir, based on the soil and water assessment tool (SWAT) model driven by the China
Meteorological Assimilation Driving Datasets for the SWAT model (CMADS). The results show that
the CMADS could be applied to drive the SWAT model in Northeast China. The dynamic process of
TN accumulation indicates that the distribution of TN inputted into the reservoir fluctuated with
the dry and wet seasons from 2009–2016, which was mainly governed by the amount of runoff.
The annual average TN input and output fluxes of the Biliuhe reservoir were 274.41 x 10*4 kg and
217.14 x 10*4 kg, which meant that 19.76% of the TN input accumulated in the reservoir. Higher TN
accumulation in the reservoir did not correspond to a higher TN load, due to the influence of flood
discharge and the water supply. Interestingly, a higher TN accumulation efficiency was observed in
normal hydrological years, because the water source reservoir always stores most of the water input
for future multiple uses but rarely discharges surplus water. The non-point sources from fertilizer
and atmospheric deposition and soils constituted the highest proportion of the TN input, accounting
for 35.15%, 30.15%, and 27.72% of the average input. The DBWD (Dahuofang reservoir to Biliuhe
reservoir water diversion) project diverted 32.03 x 104 kg year-1 TN to the Biliuhe reservoir in
2015–2016, accounting for 14.05% of the total annual input. The discharge output and the BDWD
(Biliuhe reservoir to Dalian city water diversion) project output accounted for 48.75% and 47.74%,
respectively. The effects of inter-basin water diversion projects should be of great concern in drinking
water source water system management. There was a rising trend of TN level in the Biliuhe reservoir,
which increases the eutrophication risk of the aquatic ecosystem. The TN accumulated in the sediment
contributed to a large proportion of the TN accumulated in the reservoir. In addition to decreasing
the non-point source nitrogen input from the upper basin, discharging anoxic waters and sediment
with a high nitrogen concentration through the bottom hole of the dam could alleviate the nitrogen
pollution in the Biliuhe reservoir. |
Language: | English |
Keywords: | total nitrogen; accumulation; SWAT model; CMADS; Biliuhe reservoir |