中文关键词
分层水库沉积物-间隙水氮营养盐垂向分布脱氮 英文关键词stratified reservoirsediment-interstitial waternitrogenvertical distributiondenitrification |
作者 | 单位 | E-mail | 刘静思 | 三峡大学水利与环境学院, 宜昌 443002 | 2659889380@qq.com | 朱晓声 | 三峡大学水利与环境学院, 宜昌 443002 | | 胡子龙 | 三峡大学水利与环境学院, 宜昌 443002 | | 张思思 | 湖北工业大学土木建筑与环境学院, 河湖生态修复与藻类利用湖北省重点实验室, 武汉 430068 | | 杨正健 | 三峡大学水利与环境学院, 宜昌 443002 | 656637841@qq.com | 纪道斌 | 三峡大学水利与环境学院, 宜昌 443002 | | 刘德富 | 三峡大学水利与环境学院, 宜昌 443002 湖北工业大学土木建筑与环境学院, 河湖生态修复与藻类利用湖北省重点实验室, 武汉 430068 | |
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中文摘要 |
为分析不同分层水库沉积物间隙水氮营养盐垂向分布差异的原因,通过监测香溪河库湾、长江干流和小湾水库3种水域上覆水-间隙水环境特征,分析了不同分层水域沉积物间隙水氮营养盐垂向分布特征,并探讨了造成3种水域沉积物间隙水氮营养盐分布差异的原因.结果表明:①长江干流与香溪河库湾沉积物间隙水ρ(TN)随深度逐渐升高,而小湾水库ρ(TN)在12 cm处达到最大,底层呈"C"型分布;长江干流和香溪河库湾沉积物间隙水ρ(NH4+)随深度呈升高趋势,小湾水库底层含量略高于表层,整体上无显著变化,且长江干流与香溪河库湾ρ(NH4+)整体上高于小湾水库,浓度变化范围分别为:0.512~8.289、0.968~9.307和0.950~1.500mg·L-1;3个水域沉积物间隙水ρ(NO3-)垂向分布特征均与ρ(NH4+)相反,且香溪河库湾与长江干流ρ(NO3-)高于小湾水库,浓度变化范围分别为:0.143~0.674、0.107~0.647和0.050~0.051mg·L-1;② 3种水体理化指标垂向分布特征也存在明显差异.长江干流水温垂向无明显变化,垂向稳定系数N2<5×10-5 s-2,水体混合均匀,溶解氧垂向变化范围为:6.180~6.318mg·L-1;香溪河库湾中上游水温垂向上呈降低趋势,下游水温呈阶梯状分布,N2均大于5×10-5 s-2,处于稳定分层状态,溶解氧呈"C"型分布特征;小湾水库在水深5~15 m和54~70 m出现明显分层,溶解氧在水温梯度较大处显著降低,80 m后,沿水深无明显变化;③上覆水水动力、溶解氧分布以及沉积物环境差异是造成3种水域间隙水氮营养盐垂向分布差异的主要原因,且香溪河库湾间隙水氨氮和硝氮含量较高,可能提高反硝化速率,进而有助于水域脱氮,减少水域氮负荷. |
英文摘要 |
To determine the reasons for the variation in the vertical distribution of nitrogen in sediment interstitial waters between different stratified reservoirs, the characteristics of overlying water-interstitial water in Xiangxi Bay, Yangtze River mainstream, and Xiaowan Reservoir were monitored. The vertical distribution of nitrogen in sediment interstitial waters in these different stratified waters were then analyzed, and the reasons for the variation in this distribution were assessed. The results showed:① the ρ(TN) in the sediment interstitial waters of the Yangtze River mainstream and Xiangxi Bay gradually increased with depth, while that of Xiaowan Reservoir reached its maximum at 12 cm and the bottom layer presented a "C" distribution. The ρ(NH4+) in the sediment interstitial waters of the Yangtze River mainstream and Xiangxi Bay exhibited an increasing trend with depth, while that of Xiaowan Reservoir was slightly higher in the bottom layer than in the surface layer, although the change with depth was not significant. Overall, the ρ(NH4+) in the sediment interstitial waters of the Yangtze River mainstream and Xiangxi Bay was higher than that of Xiaowan Reservoir, and the concentration ranges were as follows:0.512-8.289 mg·L-1, 0.968-9.307 mg·L-1, and 0.950-1.450 mg·L-1. The vertical distribution of the ρ(NO3-) in the sediment interstitial waters of all three waterbodies were opposite to that of ρ(NH4+). Moreover, the ρ(NO3-) in the sediment interstitial waters of Xiangxi Bay and the Yangtze River mainstream was higher than that of Xiaowan Reservoir. The concentration ranges were as follows:0.143-0.674 mg·L-1, 0.107-0.647 mg·L-1, and 0.050-0.051 mg·L-1. ② There were also significant differences in the vertical distribution of physical and chemical indices in the three water bodies. There was no significant change in the vertical distribution of the water temperature in the Yangtze River mainstream and the N2 value was <5×10-5 s-2; hence, the water was well mixed, and the vertical range of the dissolved oxygen content was 6.180-6.318 mg·L-1. The water temperature in the upper and middle reaches of Xiangxi Bay decreased vertically, while the water temperature in the lower reach presented a ladder-like distribution and the N2 values were all>5×10-5 s-2; thus, the water was in a stable stratified state and the dissolved oxygen content presented a "C" distribution. There was obvious stratification at the depths of 5-15 m and 54-70 m in Xiaowan Reservoir. The dissolved oxygen content decreased significantly at higher water temperature gradients, and there was no significant change along the water depth below 80 m. ③ The main reasons for the variation in the vertical distribution of nitrogen in the sediment interstitial waters of the three waterbodies were the differences in the overlying water hydrodynamics, dissolved oxygen distribution, and sediment environment. The ρ(NH4+) and ρ(NO3-) were higher in Xiangxi Bay, which may have increased the denitrification rate and subsequently have helped to remove nitrogen and reduce the nitrogen load in these waters. |
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