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1990~2003年洪湖水体环境质量演变分析 总被引:16,自引:0,他引:16
以详细的水质监测资料为基础,采用标准指数法并结合实地调查,分析了1990~2003年洪湖水质的变化状况。结果表明,14 a间,洪湖水质类别以Ⅲ类和Ⅳ类为主。水质恶化的驱动因子是氮、磷及其它有机污染物。1991年到1994年期间,水体中氨氮(NH4 -N)占溶解无机氮(D IN)的比例逐年增高;1995~2003年,以氨氮和硝酸盐(NO3--N)同时作为水体中溶解无机氮的主要存在形式,与1990~1994年的水质状况相比,亚硝酸盐(NO2--N)所占的比例呈增加之势。氨氮、硝酸盐和亚硝酸盐的年际变化表明,洪湖水体自净能力在逐渐降低。以总磷(TP)、总氮(TN)和溶解无机氮(D IN)作为评价指标,洪湖水体已属中富营养型湖泊。洪湖水质演变与该区域人类活动(围湖造田、围网养殖等)以及江湖连通的变化对水环境的作用相耦合。 相似文献
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洞庭湖与长江水体交换能力演变及对三峡水库运行的响应 总被引:6,自引:0,他引:6
运用洞庭湖区与长江干流相关控制站1951-2010 年实测水文数据, 在分析江湖水力关系的基础上, 从不同时间尺度分析江湖水体交换能力的演变特征及其对三峡水库运行的响应。结果表明:① 7-9 月长江荆南三口对洞庭湖的补给能力较强, 1-3 月洞庭湖对长江的补给能力较强;② 江湖水体交换系数具有明显的年代际波动, 其中1951-1958 年、1959-1968 年荆南三口对湖泊的补给能力较强, 而2003-2010 年湖泊对长江的补给能力增强;③ 三峡水库运行后无论是典型年还是在水库不同调度方式运行期, 三口分泄能力减弱, 入湖水量减少, 而因四水入湖水量占绝对优势, 湖泊对长江的补给能力明显增强;④ 尽管影响江湖水体交换能力的因素极为复杂, 但从总体上讲, 除受流域降水波动影响外, 江湖水体交换能力在不同时间尺度上的演变特征及其过程均随着江湖水体交换量的变化而变化, 说明江湖水体交换能力强度与江湖水体交换量之间存在着彼此消长的关系。 相似文献
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鄱阳湖与长江之间存在着复杂的相互作用关系,决定着江湖水沙交换,对整个区域的水资源、防洪、航运、生态环境等均具有重要影响。本文基于能量的观点,在从新的角度解释鄱阳湖和长江相互作用原理的基础上,构建了江湖相互作用的表征指标—能差Fe,对20世纪50年代以来江湖作用关系变化进行了研究。结果表明,自20世纪50年代以来,Fe值整体呈现增加趋势,说明长江作用减弱,鄱阳湖作用不断增强。三峡水库蓄水运用对江湖关系产生了重要影响,进一步削弱了长江作用。从年内变化来看,由于三峡水库的调节,枯水期长江作用略有增强,汛末长江作用减弱较大。江湖作用一定程度上影响着湖区旱涝灾害的产生,当五河来流较大且长江顶托作用明显时,易发生洪涝;当五河来流较小但又对长江有明显的补水作用时,易发生旱情,三峡水库蓄水使湖区9-10月更易发生干旱。 相似文献
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洪湖湖泊环境演变与湿地生态产业发展的思考 总被引:1,自引:1,他引:0
从洪湖的形成与生态功能地位入手,阐述了洪湖湖泊环境演变、水产业过度开发对洪湖湿地生态的影响,分析了洪湖湿地生态环境变化的主要原因,提出了发展休闲渔业和湿地生态旅游产业化的基本思路,将区域新型产业经济发展与流域生态文化建设相结合,确定人水和谐为洪湖生态产业经济的发展战略。 相似文献
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洞庭湖年径流泥沙的演变特征及其动因 总被引:18,自引:2,他引:16
通过对洞庭湖1951~1998年径流泥沙演变过程及其驱动力的全面分析表明, 径流泥沙关系密切, 其相关系数r = 0.9013。年径流量、年输沙量总体均呈同步减少趋势, 在演变过程中表现出明显的阶段性。由于湘、资、沅、澧四水流域产水量大, 森林覆盖率达52%以上, 连年兴建的水利工程及工农业、生活用水量的增加, 未能对四水河流水文特征产生根本性的影响, 其入湖径流泥沙基本处于稳定状态, 故没有对湖泊径流泥沙的演变造成深刻影响。而由长江中游河段的调弦口堵口, 下荆江系统裁弯和葛洲坝截流所引起的3次江湖水沙关系调整, 即是导致洞庭湖径流泥沙缓减速减的主动因子。 相似文献
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近50年来长江与鄱阳湖水文相互作用的变化 总被引:13,自引:2,他引:11
通过分析1957-2008 年长江与鄱阳湖相互作用的基本特征及其与长江中游、鄱阳湖流域的径流量和气候变化的关系,并用2004-2006 年三峡水库蓄水、放水量的数据,定量地计算和比较了三峡水库运行和区域气候变化对长江与鄱阳湖相互作用的影响程度,得出如下主要结论:1)从年际、年代际尺度上来看,鄱阳湖流域的气候变化和五河入湖流量是鄱阳湖水位和水量变化的主要因素,同时也在很大程度上决定了长江与鄱阳湖相互作用关系及其强弱变化。2) 长江与鄱阳湖的相互作用强度是此消彼长的关系。从季节来看,鄱阳湖对长江的较强作用主要在4-6月,而长江对鄱阳湖的较强作用主要发生在7-9 月。3) 三峡水库运行并没有改变长江与鄱阳湖作用的基本特征,在多数季节三峡水库的影响不足以解释长江径流量变化的10%,但是水库在不同季节的蓄水或放水在一定程度上影响了江湖作用的季节变化和鄱阳湖流域的旱涝机率。4-6月的放水加强了长江作用,由于此时正值鄱阳湖流域的雨季,增强的长江作用在湿润气候的环境下可能增加初夏鄱阳湖流域发生洪涝的概率;7-9 月的少量蓄水则减弱长江对鄱阳湖的作用,降低了湖区洪涝的概率;而10 月份三峡水库的大量蓄水可能增加鄱阳湖流域的旱季干旱发生率。 相似文献
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实施流域生态管理的长江中下游湿地保护探讨 总被引:4,自引:1,他引:4
长江中下游地区湿地分布广泛且类型多样,是我国淡水湖泊分布最集中和最具有代表性的地区。为了从根本上解决长江中下游湿地利用面临的问题,实现湿地资源的可持续利用,保护湿地环境,解决区内上、下游用水的供需矛盾,实现水资源的优化配置,调动区域湿地保护的积极性和主动性,有必要遵循湿地流域分布规律,应用流域生态学最新理论与实践成果,进行流域生态管理。一方面,要从流域角度处理好几大江湖关系、蓄泄关系、湖垸关系和山湖(河)关系等;另一方面,在流域内建立统一协调机制,对流域湿地进行保护与合理利用、合理布局和统一规划;同时在保护的前提下,科学合理地利用长江中下游湿地资源,开拓新的生产力。 相似文献
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为分析荆南三口河系水位演变规律与江湖水量交换关系。依据1956—2017年荆南三口、湖南四水、洞庭湖城陵矶站以及长江干流枝城站月平均水位及流量和该流域8个雨量站的降水数据,运用Mann-Kendall趋势检验法、回归分析、流量年特征值等方法研究了三口水位的时序演变特征及其与流量、降水、江湖水量交换、人类活动的关系。结果表明:① 与阶段一(1956—1966年)相比,阶段二(1967—1980年)、三(1981—2002年)、四(2003—2017年)河系年平均水位、年最高水位分别下降0.74 m、0.37 m,年最低水位上升0.07 m;② 在涨(4—5月)、丰(6—9月)、退(10—11月)、枯(12月—次年3月)四个水文节点上,最低水位降幅最大(-0.98 m),平均水位次之(-0.78 m),最高水位最小(0.55 m),并将其降幅按水文节点排序依次为退水期(-0.95 m)>丰水期(-0.61 m)>涨水期(-0.21 m)>枯水期(0.15 m);③ 河系水位变化与其流量变化有着较好的一致性(二者的相关系数r =0.65),与降水量相关性较弱(r =-0.16),但2002—2017年相对干旱的气候加剧了河系水位的下降。从总体上看,长江枝城来水量减少和以水利工程为代表的人类活动方式是导致荆南三口河系特征水位下降的主要驱动因素。 相似文献
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鄱阳湖流域水文变化特征成因及旱涝规律 总被引:9,自引:2,他引:7
本研究分析了1960-2008年鄱阳湖流域的气候和水文变化特征,用水量和能量平衡关系解释和印证了这些特征,并由此揭示了鄱阳湖流域水文变化特征的成因及干旱和洪涝发生的规律.得到以下主要结论:1)正常或偏湿年份鄱阳湖流域6月份容纳水量能力已达到饱和,若6-7月降水量超出正常年份,则流域超饱和,洪涝发生.长江中上游降水量7月份的异常偏多会对鄱阳湖流域的洪涝起触发和强化作用.2)鄱阳湖流域7-10月蒸发量大于降水量,特别是7-8月蒸发量大于降水量的一倍以上,所以若4-6月流域降水量少于平均年同期量的20%以上,则累积效应使秋旱发生.当初冬(11月)降水偏少时,秋旱可持续到来年的初春,形成严重的春旱.长江中上游降水量对鄱阳湖流域的春旱没有直接影响,但7-8月降水量偏少时则对秋旱起重要的强化作用.3)长江对鄱阳湖流域的水文过程和旱涝的发生、发展的影响主要在7-8月的“长江与鄱阳湖耦合作用”时期和9-10月的“弱长江作用”期. 相似文献
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Evolution characters of water exchange abilities between Dongting Lake and Yangtze River 总被引:3,自引:0,他引:3
Chaomin Ou Jingbao Li Yongqiang Zhou Weiyan Cheng Yan Yang Zhonghua Zhao 《地理学报(英文版)》2014,24(4):731-745
By using field-survey hydrological data of the related control stations in Dongting Lake and the Yangtze River mainstream in 1951–2010, the evolution characters of water exchange abilities between the two water bodies and their response to the operation of the Three Gorges Reservoir (TGR) from different time scales are analyzed based on their hydraulic relations. The results are shown as follows. Firstly, during July-September, the replenishment ability of Three Outlets to Dongting Lake is stronger, and in January-March, the replenishment ability of Dongting Lake to Yangtze River is stronger. Secondly, there has been an obvious inter-decadal wave on the water exchange coefficient between Dongting Lake and Yangtze River. In 1951–1958 and 1959–1968, the replenishment ability of Three Outlets to Dongting Lake was stronger, but in 2003–2010, the replenishment ability of Dongting Lake to Yangtze River has been strengthened. Thirdly, the spill-division ability of Three Outlets weakens, and the water of Dongting Lake coming from Three Outlets decreases either in typical years or under different dispatching modes of the TGR after the operation of the Three Gorges Reservoir. Furthermore, the water of Dongting Lake coming from Four Rivers takes the dominant position, which obviously enhances the replenishment ability of Dongting Lake to Yangtze River. Fourthly, if the effect of the runoff fluctuation in the basin is not considered, the evolution characters of the exchange capacities and the exchange process between Dongting Lake and Yangtze River in different time scales are generally changed with the variation of the water exchange amount between them, although the factors influencing the water exchange capacities between them is very complex. These show that there is an in-line growth or decline relation between the river-lake water exchange ability and the river-lake water exchange amount. 相似文献
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The complex relationship between the Yangtze River and Poyang Lake controls the exchange of water and sediment between the two,and exerts effects on water resources,flooding,shipping,and the ecological environment.The theory of energy is applied in this paper to investigate the physical mechanisms that determine the nature of the contact between the Yangtze River and Poyang Lake and to establish an energy differenceindex to quantify the interactions between the two systems.Data show that Fe values for this interaction have increased since the 1950s,indicating a weakening in the river effect while the lake effect has been enhanced.Enclosure of the Three Gorges Reservoir(TGR)has also significantly influenced the relationship between the river and the lake by further reducing the impacts of the Yangtze River.The river effect also increases slightly during the dry season,and decreases significantly at the end of the flooding period,while interactions between the two to some extent influence the development of droughts and floods within the lake area.Data show that when the flow of the five rivers within this area is significant and a blocking effect due to the Yangtze River is also clearly apparent,floods occur easily;in contrast,when the opposite is true and the flow of the five rivers is small,and the Yangtze River can accommodate the flow,droughts occur frequently.Construction and enclosure of the TGR also means that the lake area is prone to droughts during September and October. 相似文献
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The blocking or reversing effect of the downstream trunk river on its tributary lakes is an essential aspect of river-lake hydraulics. To measure how and the extent to which a trunk river can influence its tributary lakes, we made a case study in Changjiang River and one of its tributary lakes, Lake East Dongting (Lake ED) during a 35-year study period (1980–2014). Specifically, we investigated Lake ED’s discharge ability into Changjiang River using stage-discharge relationship curves, and hence the changes of the lake discharge ability under different hydrologic conditions of the Changjiang River. The results show that (1) the Changjiang River does exert a huge impact on the water regimes of Lake ED. And this impact varies seasonally. A variation of 3000 m3/s in Changjiang River’s runoff would change the lake water level by about 1.1 m in dry seasons, by 0.4 m in wet seasons, and by 0.6 m during severe summer floods. (2) Changes in the Changjiang River runoff triggered by the Three Gorges Dam since 2003 have led to dramatic water regime variations in Lake ED. Other factors, including reduction of lake inflow and the lake bed erosion, also exacerbated the water regime variations in Lake ED. 相似文献
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The geological and meteorological setting of the Jianghan–Dongting lake area leads to high precipitation and siltation, but poor water discharge, thus the area is frequently flooded. In the past the river–lake relationship of the Middle Yangtze has been variable but has deteriorated recently under increasing human influence. The Jianghan Plain of the Middle Yangtze becomes a waterlogged lowland under the constant threat of flooding from the perched Jingjiang River. Due to siltation and land reclamation the Dongting Lake has lost most of its regulatory function for the river and has become increasingly vulnerable to flood disasters. The Middle Yangtze River has been undergoing siltation, resulting from a downstream decline of sediment transport capacity, resulting in the elevation of the flood level above the lowlands. Heightening of the levees has caused further siltation of the channel.The Three Gorges Reservoir will provide a buffering period of 50–80 years, during which much of the silt will be trapped in the reservoir and scouring downstream may occur. We should utilize this period to work out an overall resolution to the problem. Construction of a water and silt diversion project in the Honghu Lake and surrounding areas may resolve this problem in the dangerous Chenglingji–Wuhan Segment of the Yangtze. Widening the canals connecting the Middle Yangtze and Han Rivers may function as a discharge-dividing channel of the Yangtze, which may prove to be beneficial. 相似文献
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Applying energy theory to understand the relationship between the Yangtze River and Poyang Lake 总被引:1,自引:1,他引:0
The complex relationship between the Yangtze River and Poyang Lake controls the exchange of water and sediment between the two, and exerts effects on water resources, flooding, shipping, and the ecological environment. The theory of energy is applied in this paper to investigate the physical mechanisms that determine the nature of the contact between the Yangtze River and Poyang Lake and to establish an energy difference (Fe) index to quantify the interactions between the two systems. Data show that Fe values for this interaction have increased since the 1950s, indicating a weakening in the river effect while the lake effect has been enhanced. Enclosure of the Three Gorges Reservoir (TGR) has also significantly influenced the relationship between the river and the lake by further reducing the impacts of the Yangtze River. The river effect also increases slightly during the dry season, and decreases significantly at the end of the flooding period, while interactions between the two to some extent influence the development of droughts and floods within the lake area. Data show that when the flow of the five rivers within this area is significant and a blocking effect due to the Yangtze River is also clearly apparent, floods occur easily; in contrast, when the opposite is true and the flow of the five rivers is small, and the Yangtze River can accommodate the flow, droughts occur frequently. Construction and enclosure of the TGR also means that the lake area is prone to droughts during September and October. 相似文献
17.
《地理学报(英文版)》2010,(5)
Based on the measured hydrological data from 1951 to 2008,the chain hydrological effect between Jingjiang River and Dongting Lake is analyzed by comparative method after the Three Gorges Project operation.The result indicates that 1) the scouring amount in Jingjiang River made up 78.9% of the total from Yichang to Chenglingji,and its average scouring intensity was higher than the latter;2) the water and sand diversion rates at the three outlets of the Jingjiang River were reduced by 2.33% and 2.78% separately;3) the proportion of multi-year average runoff and sediment through the three outlets in the total into the Dongting Lake decreased by 7.7% and 24.4% respectively;4) in Dongting Lake,the speed of sediment accumulation was lowered by 26.7%,in flood season,the runoff amount was 20.2% less than the multi-year average value,leading to seasonal scarcity of water year by year.The former prolonged the lake life,while the latter induced droughts in summer and fall in successive years,shortage of drinking and industrial water,shipping insecurity,as well as ecological problems such as decrease of birds and quick increase of Microtus fortis;5) The multi-year average values of sediment and flood transporting capacity at the lake outlet were respectively increased by 26.6% and 3.7%,the embankments were protected effectively.Then,to adapt to the new change of the river-lake relation,some suggestions were put forward,such as optimizing further operation program of the Three Gorges Reservoir,reexamining the idea of river and lake regulation,and maintaining connection of the river and the lake. 相似文献
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CHANG Jiang LI Jingbao LU Dianqing ZHU Xiang LU Chengzhi ZHOU Yueyun DENG Chuxiong 《地理学报》2010,20(5):771-786
Based on the measured hydrological data from 1951 to 2008, the chain hydrological effect between Jingjiang River and Dongting Lake is analyzed by comparative method after the Three Gorges Project operation. The result indicates that 1) the scouring amount in Jingjiang River made up 78.9% of the total from Yichang to Chenglingji, and its average scouring intensity was higher than the latter; 2) the water and sand diversion rates at the three outlets of the Jingjiang River were reduced by 2.33% and 2.78% separately; 3) the proportion of multi-year average runoff and sediment through the three outlets in the total into the Dongting Lake decreased by 7.7% and 24.4% respectively; 4) in Dongting Lake, the speed of sediment accumulation was lowered by 26.7%, in flood season, the runoff amount was 20.2% less than the multi-year average value, leading to seasonal scarcity of water year by year. The former prolonged the lake life, while the latter induced droughts in summer and fall in successive years, shortage of drinking and industrial water, shipping insecurity, as well as ecological problems such as decrease of birds and quick increase of Microtus fortis; 5) The multi-year average values of sediment and flood transporting capacity at the lake outlet were respectively increased by 26.6% and 3.7%, the embankments were protected effectively. Then, to adapt to the new change of the river-lake relation, some suggestions were put forward, such as optimizing further operation program of the Three Gorges Reservoir, reexamining the idea of river and lake regulation, and maintaining connection of the river and the lake. 相似文献