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1.
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
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黄河下游河道泥沙存贮-释放及其临界条件 总被引:1,自引:1,他引:0
确定了黄河下游河道处于泥沙存贮-释放临界状态的水沙临界条件。当场次洪水平均含沙量小于31.68 kg/m3,或者来自中游多沙粗沙区场次洪水来沙量小于4 543×104 t,下游河道将由泥沙存贮状态变为泥沙释放状态。当河口镇以上清水区径流占场次洪水总径流量比率大于0.70时,也会由泥沙存贮状态变为泥沙释放状态。场次洪水泥沙输移比随洪水平均流量的增到而增大,流量为4 000 m3/s(相当于平滩流量)时达到峰值,此后有所减少。这表明,平滩流量时泥沙存贮最少,低于平滩流量和高于平滩流量时泥沙存贮均增大。 相似文献
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北京市耕地资源价值体系及价值估算方法 总被引:23,自引:1,他引:22
北京市为例尝试设计了耕地资源价值体系, 分析其价值关系, 进而探讨耕地资源经 济价值、社会保障价值、生态价值的估算方法, 并对北京市1990-2005 年耕地价值进行了定 量测算。研究结果表明: ① 北京市耕地资源单位面积经济价值呈较快增长, 1990 年为 12.57×104 元/hm2, 2005 年为108.12×104 元/hm2; ② 耕地资源社会保障价值供给能力和农 村居民的需求水平相距甚远, 1997 年供给能力为49.19×104 元/hm2, 需求水平为160.56×104 元/hm2, 2005 年供给能力为74.82×104 元/hm2, 需求水平为305.48×104 元/hm2。可见, 耕 地作为农民重要的社会保障资源已不堪重负, 农村社会保障体系亟待建立; ③ 生态价值供给 能力总体呈下降趋势, 1994 年达到171.21×108 元, 2005 年为70.87×108 元, 大量耕地减少 是重要的影响因素。但基于人口增加和人们生活水平不断提高, 生态价值的总体需求和多元 需求呈不断增长趋势, 所以需要保持和提高耕地表面的植被覆盖度, 为此政府有必要对农民 因种植耕地给予其一定的生态补偿。 相似文献
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洪水资源化是解决喀斯特地区水资源严重缺乏的有效途径。文章在贵州省喀斯特地区选取40个流域作为研究样区,利用面向对象技术的监督分类型方法,提取典型喀斯特地貌类型;分析流域样区特征,利用系统聚类法,将其划分为6种流域类型,即是:喀斯特低中山型(Ⅰ)、峰丛谷地型(Ⅱ)、混合型(Ⅲ)、峰林盆地(溶原)型(Ⅳ)、峰丛洼地型(Ⅴ)和峰林地貌型(Ⅵ);利用相关分析方法,分析不同地貌空间配置对洪水径流特征的影响,探索地貌空间配置对洪水的分配与承载规律,从流域结构角度研究地貌空间配置对洪水资源化的实现。研究表明:1)洪水径流模数、径流系数及其Cv值曲线呈现“双峰型”分布,且分别在峰丛谷地型流域(Ⅱ)和峰丛洼地型流域(Ⅴ)达极大值;2)不同流域类型实现洪水资源利用总量,从大到小排序为:Ⅴ(6.22×108 m3)>Ⅰ(2.88×108 m3)>Ⅵ(1.49×108 m3)>Ⅱ(1.34×108 m3)>Ⅳ(1.25×108 m3)>Ⅲ(0.55×108 m3);3)除峰丛谷地型(Ⅱ)和混合型(Ⅲ)流域外,所有流域类型的地下洪水资源总量大于地表洪水资源总量。喀斯特流域的洪水资源化,深受喀斯特地表的起伏及其流域侵蚀基准面和溶蚀基准面的控制。 相似文献
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三峡水库蓄水后荆江洲滩变化特征 总被引:4,自引:0,他引:4
目前对三峡水库蓄水后荆江河段的洲滩演变还缺乏完整认识。基于三峡水库蓄水前后枯水期遥感影像,分析了荆江洲滩的冲淤变化与分布及形态演变。结果表明,蓄水后荆江洲滩总面积持续冲刷减小,累计冲刷4.56 km2,大部分发生在蓄水后前6年(冲刷速率0.55 km2/a)。上、下荆江洲滩的冲淤演变存在差异性。上荆江洲滩总面积一直处于冲刷萎缩中,且其强度明显大于下荆江,累计冲刷6.46 km2;下荆江前期(2002-2009年)冲刷、后期(2009-2015年)淤增,累计淤1.90 km2。在冲淤分布上,上荆江凸岸滩持续冲刷萎缩,凹岸滩前期冲刷、后期略有淤增,心滩(洲)前期淤积增长而后期冲刷萎缩;下荆江主要是凸岸滩冲刷,凹岸滩和心滩(洲)有所发展。根据滩体位置活动和冲淤动态性,荆江心滩(洲)演变被划分为8种典型类型。在形态演变上,上荆江以凸岸突出滩体和边滩发育的凹岸滩冲刷显著,形态变化不大。下荆江凸岸滩上游弯侧冲蚀后退、湾顶退缩、下游弯侧淤积伸长,形态趋向低弯扁平化,在高弯曲特定河湾平面形态格局下凸岸冲刷—淤积过程延伸到相邻河湾凹岸,成为下荆江凹岸滩和心滩淤积发展的重要因素,但淤积一般不越过凹岸湾顶。 相似文献
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据博斯腾湖流域1958-2010年期间主要河流开都河、黄水沟、清水河、孔雀河的逐年流量资料,结合焉耆盆地降水、蒸发要素的同期观测资料,对大湖区的逐年水量收支进行计算,并依据水量平衡原理对博湖大湖区残差水量进行了逐年分析。结果表明:(1)1958-2010年期间年均入湖水量14.34×108 m3/a,其中入湖河水约占95%;年均输出水量13.96×108 m3/a,其中大湖区输入孔雀河水量约占43%,湖面蒸发耗水量占57%;湖区年均蓄水量71.57±3.92×108 m3108 m3/a,湖水年均水位为1 047.01±0.94 m;(2)极端水文年度水量平衡分析指出:1986年为最枯年份,入湖河水是多年平均值的62%,而出湖河水量是多年平均值的153%,导致年内湖区水位下降0.94 m;2002年最丰年份入湖河水是多年平均值的2.6倍,致使年内水位上升0.80 m;(3)残差水量逐年“正负”变化指出,湖水与地下水之间存在互补关系,过去53 a间湖水补给地下水的年均水量为0.87×108 m3/a。 相似文献
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生态环境敏感性分析对于生态环境功能得到保护和恢复,资源得到高效利用,生态安全得到保障,区域可持续发展能力得到增强具有重要作用。本文根据巴音郭楞蒙古自治州自然地理特征,采用GIS分析和专家集成方法,分别进行了巴州土壤侵蚀敏感性、土地沙漠化敏感性、土壤盐渍化敏感性和生物多样性及生境敏感性评价,最后展开生态环境敏感性综合研究。结果表明:巴州生态环境敏感性共分为极敏感、高度敏感、敏感、轻度敏感以及不敏感5个等级。生态环境极敏感区面积为2.7×104 km2,占全州面积5.7%;高度敏感区为12.7×104 km2,占26.4%;敏感区面积为14.8×104 km2,占30.8%;轻度敏感地区为7.9×104 km2,占16.4%;不敏感区面积为10.0×104 km2,占20.7%。 相似文献
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基于实际粮食产量与抛荒耕地种植粮食作物条件下粮食总产量关系的分析方法有助于促进耕地红线制度改进。依据全国粮食总产量、种植面积与耕地面积数据,构造2016-2033 年粮食产量与耕地面积红线耦合的基本、法定、过渡、新型与理想耦合红线标准;分析阶段性耦合与可持续耦合两种升级路径。研究表明:2001-2015 年,全国耕地面积与粮食产量耦合不足。据此,提出以新增建设用地指标与抛荒治理面积挂钩的政策建议;在抛荒比例11.12%的条件下,新增单位面积建设用地,治理28.85 倍抛荒耕地;2017、2021、2025、2029、2033 年分别实现有效利用1.200×108 hm2、1.243×108 hm2、1.279×108 hm2、1.314×108 hm2、1.349×108 hm2 耕地,粮食总产量分别比基期增加4.838×106、2.4190×107、4.354 2×107、5.321 8×107、8.824 6×107 t;红线耦合系数分别达到0.882 471、0.909 740、0.937 008、0.950 643与1;有效利用耕地增加12.5%,粮食总产量提升14.2%。 相似文献
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长江来沙锐减与海岸滩涂资源的危机 总被引:19,自引:3,他引:16
利用小波分析方法对1951~2004年大通站系列水、沙和流域降水资料进行周期性和趋势性分析,利用Arc-GIS软件对长江三角洲海图进行滩涂面积计算和冲淤剖面分析,并于2002年5月~2005年7月在长江三角洲前缘的南汇岸段进行逐日潮滩高程测量,以进行三峡水库蓄水前后滩面冲淤的对比。结果表明:尽管气候变化导致流域平均降水量以及大通径流量和输沙率存在2~3年和8~9年的波动周期 (P < 0.05),但大通输沙率从1960年代末开始出现明显的下降趋势 (P< 0.001),三峡工程运行后的2003年 (6月开始蓄水) 和2004年连续2年创历史新低,流域水库的修建是导致这一下降趋势的根本原因。长江来沙量的锐减正在导致三角洲前缘滩涂从淤涨向侵蚀转化。预测认为:流域人类活动还将继续导致长江入海泥沙量的下降,今后几十年的大通输沙率将从目前的 1.5×108 ~2×108 t/a下降到1×108 t/a左右;泛长江三角洲海岸滩涂资源将面临严峻挑战。 相似文献
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According to a long series of measured sediment data, the sedimentation effects of the Dongting Lake Area (DLA) were studied in light of the relationship between sedimentation characteristics and resources and environment. The result shows that the long-term deposition and the impact of human activities have led to a cycle of the evolution of sedimentation pattern, resulting in sediment disaster effects and resources effects in the DLA. The main features are as follows: 1) The water beach, silt beach, lake marsh beach, reed beach and other types of beach shaped by sedimentation effects constitute the main body of the giant lake system. 2) The disaster chains are induced, i.e., sedimentation → marshland expansion and reclamation → flood function decline, fish resource depletion, biodiversity reduction disaster chain, sedimentation → marshland expansion → floods, water pollution disaster chain, sedimentation → marshland floating vegetation rising → schistosomiasis, rodents virulence disaster chain, sedimentation → flood embankment bursting → land desertification disaster chain. 3) Sedimentation has created about 98.13×104 hm2 of land in the past 55 years. Rational development and utilization of marshland resources have produced tremendous economic benefits. 相似文献
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洞庭湖区的泥沙淤积效应 总被引:4,自引:1,他引:3
According to a long series of measured sediment data, the sedimentation effects of the Dongting Lake Area (DLA) were studied in light of the relationship between sedimentation characteristics and resources and environment. The result shows that the long-term deposi- tion and the impact of human activities have led to a cycle of the evolution of sedimentation pattern, resulting in sediment disaster effects and resources effects in the DLA. The main features are as follows: 1) The water beach, silt beach, lake marsh beach, reed beach and other types of beach shaped by sedimentation effects constitute the main body of the giant lake system. 2) The disaster chains are induced, i.e., sedimentation → marshland expansion and reclamation → flood function decline, fish resource depletion, biodiversity reduction dis- aster chain, sedimentation → marshland expansion → floods, water pollution disaster chain, sedimentation → marshland floating vegetation rising → schistosomiasis, rodents virulence disaster chain, sedimentation → flood embankment bursting → land desertification disaster chain. 3) Sedimentation has created about 98.13×104hm2 of land in the past 55 years. Ra-tional development and utilization of marshland resources have produced tremendous eco- nomic benefits. 相似文献
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近60年洞庭湖泊形态与水沙过程的互动响应 总被引:2,自引:0,他引:2
以历史文献、图件及1951~2009年长系水沙等资料为依据,对比分析洞庭湖形态与水沙过程的互动响应,结果表明:由于湖泊形态与水沙过程存在着相互作用的关系,近60年间,水沙过程以多种形式改变湖泊形态特征值,如湖盆结构破碎、解体,水深变浅以及湖面﹑湖容依次减少1840km2及130×108m3;同时湖泊形态特征值改变也引起水沙特性变异,在1951~2002年间湖盆蓄水量呈明显的增减波动,但同流量下汛期水位普遍抬高1.2~1.90m,西﹑南﹑东洞庭湖水位变幅依次增大1.61m、1.39m和1.35m,各主要水文站前5位最高洪水位排序的年份均出现在湖面积(容积)历史最低值,泥沙淤积率为70%以上;2003年6月三峡水库蓄水及"退田还湖"后,高、中水位下湖盆调蓄量有所减少,城陵矶丰、枯水位分别降低1.12m及0.35m,西湖区与东南湖区的泥沙输出比均呈增大趋势,泥沙淤积率减至35.9%。其互动响应机制,可概化为泥沙淤积循环→湖盆结构破碎、解体,湖面湖容缩小→水沙特性异变→改变湖泊形态→水沙特性变异的互动响应动态演进模式。 相似文献
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水沙过程变化下洞庭湖区的生态效应分析 总被引:1,自引:0,他引:1
依据1951-2009年实测水文数据及多年实地考察资料,对比分析水沙过程变化对洞庭湖区生物群落及其生存环境的影响.结果表明:(1)水沙过程对生物群落及其生存环境具有多方面的生态支撑作用,水沙动态是洞庭湖生态系统的控制性变量;(2)泥沙的不断淤积,使各类植被洲滩发育与扩展,导致湖面缩小及调蓄功能减弱和天然捕捞鱼场减少;(3)各类植被洲滩相继出露和湖水位涨落交替过程,不但维系着东方田鼠种群数量及迁移的延续,还支撑着钉螺(血吸虫的中间宿主)的孳生和繁衍;(4)入湖水沙量的逐期减少,削弱了水域环境的净化能力,“四 相似文献
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三峡工程建设背景下的洞庭湖区治水方略探讨 总被引:8,自引:1,他引:7
在长江三峡工程建设的大背景下,本文分析了洞庭湖区的水灾减灾机制,探讨了洞庭湖区的治水方略,提出应充分发挥三峡水库的调蓄功能,协调江湖关系,改善冲淤关系,加强水利工程建设,实现三峡水库与湖南四水水库的优化调度 相似文献
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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
17.
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
18.
基于Copula函数的洞庭湖流域水沙丰枯遭遇频率分析 总被引:1,自引:0,他引:1
受人类活动的影响,水沙灾害事件相继发生,对人们的生产、生活造成了威胁。以洞庭湖流域代表性水文站的年径流量和年输沙量系列数据为基础,应用P-III型曲线分别拟合并求得“松滋口、太平口、藕池口”三口入湖、“湘江、资江、沅水、澧水”四水入湖和城陵矶站出湖年径流量、年输沙量的边缘分布函数,再采用水文事件遭遇分析中广泛应用的Copula函数,建立洞庭湖流域水沙联合分布模型,分析洞庭湖流域水沙丰枯遭遇频率。研究结果表明洞庭湖三口、四水和城陵矶站的水沙丰枯遭遇频率关系与洞庭湖流域的水沙运动有密切联系,运用该水沙耦合模型可以为洞庭湖流域防洪减灾提供重要的理论依据。 相似文献
19.
《The Professional geographer》2013,65(4):434-445
Abstract Jiangxi Province in southeastern China contains Poyang Lake, the largest freshwater lake in China. Poyang Lake and the lower sections of the major Jiangxi rivers flowing into the lake often flood during the early summer months. Floodwater can be several meters above the surrounding lowlands during the most severe flood events. Levees at the margins of Poyang Lake and along the Jiangxi rivers provide flood protection for about 10 million people. The number of severe floods in this region has increased rapidly during the past few decades, resulting in catastrophic levee failures. The three factors likely responsible for the increasing frequency of severe floods are (1) land reclamation and levee construction and (2) lake sedimentation, both of which reduce lake volume, and (3) increasing Changjiang water level, which slows Poyang Lake drainage. 相似文献
20.
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