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1.
三峡水库调度运行初期荆江与洞庭湖区的水文效应 总被引:12,自引:1,他引:11
以1951-2008年实测水文资料为依据,运用对比方法,分析了三峡水库调度运行初期,荆江与洞庭湖区的连琐水文效应.结果表明:①莉江冲刷星占宜昌至城陵矶段的78.9%,其平均冲刷强度也远高于该河段;②三口分流比减少2.33%、分沙比减少2.78%;③三口多年平均入湖径流泥沙比依次减少7.7%及24.4%;④洞庭湖区淤积速率减缓26.7%、汛期水最较同期多年平均值偏少20.2%,使湖区连年季节性缺水,前者对延长湖泊寿命有利,后者酿成了连年性的夏秋连旱灾害、居民饮用水、生产用水和航运等水安全问题以及涉及到了珍禽鸟类数量和种类减少,东方田鼠种群数量极度膨胀等生态系统的稳定性;⑤湖口多年平均输沙泄洪能力增强了26.6%和3.7%,避免了溃垸决堤之灾.并认为,为适应新的江湖关系变化,必须进一步优化调整三峡水库调度运行方案,重新审视江湖治理的理念,维系江湖连通的纽带. 相似文献
2.
利用增强型植被指数(enhanced vegetation index,EVI),采用Mann-Kendall方法和Sen’s斜率估计方法,研究2000~2014年洞庭湖区的植物面积及其变化趋势,以及其与水位之间的关系。研究结果表明,枯水年洞庭湖区的植物面积最大,平水年的次之,丰水年的最小;2000~2014年期间,洞庭湖区增强型植被指数的变化存在空间异质性,东洞庭湖区的大部分区域的增强型植被指数无显著变化,南洞庭湖区的大部分区域的增强型植被指数显著增大;洞庭湖区18.08%的区域的增强型植被指数显著增大,这些区域主要集中在高滩地(平均海拔为26.61 m);7.51%的区域的增强型植被指数显著减小,这些区域主要集中在低滩地(平均海拔为25.79 m);随着湖泊水位的上升,洞庭湖区植物面积在减少,当洞庭湖水位为24 m时,最适合植物生长,当洞庭湖水位低于24 m时,洞庭湖区的植物面积受水位变化的影响较小。 相似文献
3.
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
4.
在地理信息系统空间分析模块的支持下,对洞庭湖区钉螺及疫情的空间分布特征及其原因进行了深入探讨,并对两者之间的关系进行了研究;同时,通过对洞庭湖营养状态的评价,对钉螺及疫情分布与水环境质量的关系进行了研究。结果表明:洞庭湖区螺情及疫情呈现出比较复杂的空间分布特征,表现为益阳市南县及其周围地区以及长沙市望城区居民感染率和钉螺感染率均偏低;岳阳市临湘市的居民感染率与钉螺感染率之间、岳阳市湘阴县的居民感染率、耕牛感染率与钉螺感染率之间呈负相关关系;各监测点钉螺分布与疫情分布之间没有显著的相关性;洞庭湖水体的富营养化现象有利于钉螺的生存,一定程度上将加剧疫情的控制难度。 相似文献
5.
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
6.
近47年来洞庭湖区干湿的气候变化 总被引:2,自引:0,他引:2
采用M-K突变、小波分析、空间变异系数、经验正交函数分解法(EOF)和旋转经验正交函数分解法(REOF)等方法,对近47年来洞庭湖区20个测站干湿指数(Z指数)进行了分析。研究表明:洞庭湖区20世纪60年代前期和80年代为干旱期,90年代为湿润期。80年代末有向湿润转变趋势,2003年后又开始向干旱转变。洞庭湖区干湿的年际变化较小,降水相对稳定,存在3年、6年和15年、22年4个特征时间尺度,且未来几年洞庭湖区将仍处于干旱期。洞庭湖区干湿变化具有很好的主体一致性,依据空间异常类型可分为北部、中部、南部和西北部4个区域。 相似文献
7.
8.
三峡水库运行下洞庭湖盆冲淤过程响应与水沙调控阈值 总被引:4,自引:0,他引:4
以1951-2011 年洞庭湖区及荆江段干流主要控制站实测径流输沙量资料为依据,分析三峡水库不同蓄水阶段及不同调度方式下洞庭湖盆冲/淤响应,并提出上游来水来沙调控阈值。结果表明:① 荆南三(四)口流量与枝城站流量、荆南三(四)口输沙率存在极显著正相关(p < 0.0001),决定系数r2分别为0.859 及0.895。② 与三峡水库蓄水运用前(1999-2002)相比,一、二期蓄水阶段及全面试验性蓄水阶段(2008.10-2011.12)洞庭湖盆年均冲淤量由+4796.4×104 t 依次递减为+684.1×104 t、+449.8×104 t 及-559.6×104 t,湖盆冲淤率由+70.25%分别降至+31.13%、+23.56%及-42.64%。③ 预泄调度及蓄水调度期,湖盆泥沙均由以淤积为主转变为以冲刷为主,防洪补偿调度期湖盆泥沙表现为淤积,而在补水调度运用期则表现为冲刷。④ 洞庭湖盆处于冲/淤临界平衡状态时的荆南三口平均流量、输沙率及含沙量分别为970.81 m3/s、466.82 kg/s 及0.481 kg/m3。并认为,为增强湖泊调蓄功能,必须进一步优化三峡水库调度方式,合理调控下泄水沙量。 相似文献
9.
利用1258个地下水水样的水质指标数据,对洞庭湖区浅层地下水水质指标空间分异及其控制因素开展了研究。从地下水系统、氧化还原环境和第四纪沉积物物源角度,剖析了浅层地下水水质指标空间分布的内在影响因素。研究结果表明,洞庭湖区浅层地下水7个水质指标的空间分布都呈现出一定的规律性,自洞庭湖区外围至湖盆腹地,浅层地下水中的氨氮、铁元素、溶解性总固体和化学需氧量含量逐渐增大,硝酸盐氮含量的空间分布规律则与之相反,锰元素含量的空间分布独具特点,水体pH的分布呈现出西北—东南单向减小特征;洞庭湖区大范围浅层地下水中的氨氮、铁元素和锰元素含量超过Ⅲ类地下水该指标的限值,在洞庭湖区外围的零星区域,浅层地下水中的硝酸盐氮含量小幅度超标,其溶解性总固体和化学需氧量含量仅在大通湖附近的局部区域略超标;洞庭湖区的基底构造对浅层地下水系统的整体空间格局有重要影响,主要体现在对“四口”水系地下水系统、澧县盆地地下水系统、赤山隆起-大通湖地下水滞留区等的控制作用;独特的受构造格局控制的地下水系统格局宏观上决定了地下水化学场的空间分布;受地下水系统格局控制的浅层地下水水体的氧化还原电位对硝酸盐氮、氨氮、铁元素、锰元素和化学需氧量含量的空间分布有重要影响,平原区浅层地下水水体的氧化还原电位较低是氨氮、铁元素和锰元素含量大范围超标的主要原因;洞庭湖区浅层地下水的pH“西北—东南单向递减”的分布特征主要受湖区第四纪沉积物物源的空间差异的影响。 相似文献
10.
洞庭湖区1998年与1954年特大洪涝灾害比较研究 总被引:5,自引:0,他引:5
在对洞庭湖区深入调查研究的基础上,结合历史资料,从雨情、水情和灾情三个方面对比分析了1998年、1954年特大洪涝灾害的共性和个性。在此基础上揭示了1998年洞庭湖区洪涝灾害形成的原因,并提出了防治对策,为洞庭湖社会经济可持续发展和综合治疗洞庭湖提供了科学依据。 相似文献
11.
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
12.
三峡工程蓄水对洞庭湖水环境质量特征的影响 总被引:2,自引:0,他引:2
三峡工程的运行给洞庭湖水环境质量造成了直接或间接的影响。本研究运用主成分分析法筛选了水质污染指标,采用基于超标权重的综合水质标识指数法对洞庭湖水质进行了评价,并重点分析了三峡工程蓄水后洞庭湖水环境质量变化特征。主成分分析结果表明,影响洞庭湖水环境质量的主要污染指标为总氮和总磷;典型断面综合水质标识指数评价结果表明,三峡工程的运行对洞庭湖水环境质量变化有一定影响,各典型断面多年综合污染指数高于三峡工程建设前,表现为2003 年前水质多以Ⅲ类为主,2003 年后以Ⅳ类为主;ArcGIS 支持下的洞庭湖水环境质量时空分析表明,三峡工程运行后,洞庭湖水环境污染格局发生变化,表现为局部污染区域发生转移,东洞庭湖及洞庭湖出口污染最重。 相似文献
13.
The hydrological effect between Jingjiang River and Dongting Lake during the initial period of Three Gorges Project operation 总被引:2,自引:2,他引:0
Jiang Chang Jingbao Li Dianqing Lu Xiang Zhu Chengzhi Lu Yueyun Zhou Chuxiong Deng 《地理学报(英文版)》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
14.
The Dongting Lake is located in the south beach of the middle reaches of the Yangtze River. Its catchment, with an area of 262,823 km2 or about 12% of the total Yangtze River catchment, is situated between 28o43?29o32扤 and 112o54?113o8扙, and crosses Hubei and Hunan provinces in administrative division. The main tributaries include Xiangjiang, Zishui, Yuanjiang, Lishui rivers (4 Tributaries) and some local rivers, such as Miluo River, Xinqiang River and other little streams. In the nor… 相似文献
15.
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
16.
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
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
18.
The sediments of the Dongting Lake come from four channels (one of them was closed in 1959), connected with the Yangtze River, four tributaries (Lishui, Yuanjiang, Zishui and Xiangjiang) and local area, and some of them are transported into the Yangtze River in Chenglingji, which is located at the exit of the Dongting Lake, some of them deposit into drainage system in the lake region and the rest deposit into the lake. The annual mean sediment is 166,555x104 t, of which 80% come from the four channels, 18% from the four tributaries and 2% from local area, whereas 26% of the total sediments are transported into the Yangtze River and 74% deposited into the lake and the lake drainage system. Based on topographic maps of 1974, 1988 and 1998, and the spatial analysis method with geographic information system (GIS), changes in sediment deposition and erosion are studied in this paper. By overlay analysis of 1974 and 1988, 1988 and 1998, erosion and sediments deposition areas are defined. The main conclusions are: (1) sediment rate in the lake is larger than erosion rate from 1974 to 1998. The mean deposition in the lake is 0.43 m; (2) annual sediment deposition is the same between 1974-1988 and 1988-1998, but the annual volume of deposition and erosion of 1988-1998 is bigger than that in 1974-1988; (3) before the completion of the Three Gorges Reservoir, there will be 7.82x108 m3 of sediments deposited in the lake, which would make the lake silted up by 0.33 m; (4) in the lake, the deposition area is found in the north of the east Dongting Lake, the south-west of the south Dongting Lake, and the east of the west Dongting Lake; while the eroded area is in the south of the east Dongting Lake, the middle of the south Dongting Lake, the west of the west Dongting Lake, as well as Xiangjiang and Lishui river flood channels. 相似文献
19.
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