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引用本文:龚然,胡梅,续衍雪,徐力刚,蒋名亮.滆湖重建沉水植物生境对抑制沉积物再悬浮的模拟研究.湖泊科学,2024,36(5):1403-1411. DOI:10.18307/2024.0521
Gong Ran,Hu Mei,Xu Yanxue,Xu Ligang,Jiang Mingliang.Modeling the inhibition effect of recreating submerged plants habitat on sediment resuspension in Lake Gehu. J. Lake Sci.2024,36(5):1403-1411. DOI:10.18307/2024.0521
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滆湖重建沉水植物生境对抑制沉积物再悬浮的模拟研究
龚然1, 胡梅2, 续衍雪3,4, 徐力刚5,6,7, 蒋名亮5
1.南京工程学院环境工程学院, 南京 211167;2.江西省生态环境监测中心, 南昌 330037;3.生态环境部环境规划院长江经济带生态环境联合研究中心, 北京 100041;4.清华大学水利系水电工程系, 北京 100084;5.中国科学院南京地理与湖泊研究所, 湖泊与流域水安全重点实验室, 南京 210008;6.中国科学院南京地理与湖泊研究所, 鄱阳湖湖泊湿地综合研究站, 九江 332899;7.江西省鄱阳湖流域生态水利技术创新中心, 南昌 330029
摘要:
滆湖自1990s以来水生态环境变化迅速,水生植物几乎消亡,生态系统由“草型清水”湖演变为“藻型浊水”湖,其浅水特性在风力作用下常造成底床沉积物的再悬浮现象。泥沙和营养物质频繁重回上覆水体导致水质长期难以改善,故重建沉水植物生境被认为是恢复滆湖生态环境的措施之一。本文构建滆湖水环境模型,模拟和分析水动力及沉积物的再悬浮过程。研究表明,在常规风力条件下(约2.2~2.8 m/s),全湖底床切应力均值(τb)约为0.023 N/m2,全湖几乎不存在沉积物再悬浮现象,而在强风条件下(如大于10 m/s),τb可达0.45 N/m2,全湖绝大部分区域的沉积物均可以发生再悬浮,南部浅水区域及其东西沿岸为再悬浮发生的高频地区。模型设定了一种沉水植物生境的情景条件进行模拟与预测。研究结果表明,在易发生再悬浮且适合沉水植物生长的南部区域,重建覆盖度约为12%的沉水植物,可削减实际条件下τb的24.4%,从而分别降低年均和强风时刻全湖固体悬浮物(TSS)浓度的29.3%和25.1%。对一次强风过程的模拟结果表明,情景条件下τb由实际条件下的0.45 N/m2下降为0.34 N/m2,全湖TSS均值和最大值比实际条件分别下降了20.9和470 mg/L,沉水植物生境的存在对全湖TSS浓度改善效果显著。
关键词:  滆湖  沉水植物  沉积物再悬浮  数学模型  情景预测
DOI:10.18307/2024.0521
分类号:
基金项目:国家自然科学基金项目(U2240224,42307106)、南京工程学院校级科研基金项目(ZKJ201804)、江西省科技计划项目(20213AAG01012,20212BBG71002,20222BCD46002)、江西省水利厅科技项目(202325ZDKT08)和长春市科技发展计划项目(23SH03)联合资助。
Modeling the inhibition effect of recreating submerged plants habitat on sediment resuspension in Lake Gehu
Gong Ran1, Hu Mei2, Xu Yanxue3,4, Xu Ligang5,6,7, Jiang Mingliang5
1.College of Environment Engineering, Nanjing Institute of Technology, Nanjing 211167, P. R. China;2.Jiangxi Province Ecological Environmental Monitoring Centre, Nanchang 330037, P. R. China;3.Chinese Academy of Environmental Planning, United Center for Eco-Environment in Yangtze River Economic Belt, Beijing 100041, P. R. China;4.Department of Hydraulic Engineering, Tsinghua University, Beijing 100084, P. R. China;5.Key Laboratory of Lake and Watershed Science for Water Security, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing 210008, P. R. China;6.Poyang Lake Wetland Research Station, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Jiujiang 332899, P. R. China;7.Jiangxi Provincial Technology Innovation Center for Ecological Water Engineering in Poyang Lake Basin, Nanchang 330029, P. R. China
Abstract:
Lake Gehu, the second largest shallow lake in Taihu Basin, has undergone rapid water environment changes since the 1990s, with almost total loss of aquatic plants and the changing of ecological type from “macrophyte-clear” to “algae-turbid”. The sediment in this type of lake tends to suspend induced by strong wind, hence, recreation of submerged plants community was recognized to be one of the valid measures for restoring ecological environment in Lake Gehu. In this article, an environmental model was developed, to investigate the hydrodynamic process and sediment resuspension. Results show that, under normal wind condition (2.2-2.8 m/s), the mean value of bed shear stress of the whole lake is about 0.023 N/m2, which cause no sediments resuspension. However, this value can reach over 0.45 N/m2 under extreme wind condition (>10 m/s), and sediment resuspension probably occurs in the most parts of the lake. The southern shallow area and its east and west coast are the high-frequency areas where sediment resuspension occurs. A scenario of reconstructing submerged plant habitat in the area prone to sediment resuspension and suitable for plant growth (covering about 12% of the whole lake) was set for prediction analysis. The results indicate that, under scenario condition, the average annual bed shear stress of the whole lake reduced 24.4% and thus 29.3% and 25.1% for suspended solids concentration both in annual average and at the moment of strong wind, respectively. During a strong wind in simulation, the mean bed shear stress of the whole lake decreased from 0.45 to 0.34 N/m2 compared with the actual situation, and the mean and maximum concentrations of suspended solids decreased by 20.9 mg/L and 470 mg/L, respectively. The presence of submerged plant habitat is capable of significant reducing the concentration of total suspended solids in the lake.
Key words:  Lake Gehu  submerged plant  sediment resuspension  mathematical modeling  scenario prediction
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