太湖流域LUCC对水文过程的影响

基于1971年枯水年、1989年丰水年、2000年平水年3类典型代表年的逐日降雨量、逐日蒸发量以及不同时期地表覆盖遥感分类数据,以城市化快速发展地表覆盖变化明显的太湖流域为研究区域,利用太湖流域河网水量模型进行了土地利用/覆被变化的水文响应研究,分析了太湖流域1990 2000年与2000 2006年间的土地利用/覆被变化及其对水位过程的影响.不仅有利于对城市化地区水文特征变化规律深入了解,也为典型城市化地区防洪减灾提供科学可靠的依据.研究表明,太湖流域城镇化进程的加快引起了土地利用/覆被变化的主要表现是水田、水域等面积向城镇面积转化,城镇化进程加快,2000 2006年期间的城镇化速度大于1990 2000年间;下垫面的变化对太湖流域水文过程产生了明显的影响,随着城市化进程地表覆盖的变化,水位有整体升高的趋势,并且增幅加大,与城镇化速率变化趋势相一致,城镇化程度高的地方水位上升更为明显;降雨量也是水位过程的影响因素之一.     

水文非线性系统与分布式时变增益模型

论述了以Volterra泛函级数表达的流域降雨-径流非线性系统理论与概念性模拟方法. 依据流域数值高程模型、遥感信息和单元水文过程, 提出了水文非线性系统理论的时变增益模型(TVGM)和推广应用到流域时空变化模拟的分布式时变增益模型(DTVGM). 研究表明, 除了常用的非线性系统分析方法之外, 从复杂水文关系研究中另辟蹊径, 提出一种简单关系的非线性系统分析是完全有可能的. 时变增益水文模型的提出及其与一般性水文非线性系统的联系就是一个例证. 水文非线性系统方法与分布式流域水文模拟结合的DTVGM模型, 能够发挥水文系统方法与分布式水文模拟方法相结合的优点, 探索环境变化下的流域水文模拟问题. 将DTVGM分别应用到河西走廊干旱地区的黑河流域和华北地区潮白河流域实例研究, 模拟了水文时空变化以及陆面覆被变化与水文影响分析, 取得了较好的效果, 说明了其特色和应用价值.     

模型模拟梭磨河流域气候波动和土地覆被变化对流域水文的影响

针对长期以来关于森林的水文效应的争论, 选择了长江上游的一个中等流域, 分析其40年来的气候波动以及土地覆被变化情况, 利用集总式和分布式水文模型分别模拟了该流域气候波动和土地覆被变化对其水文的影响, 得出由于气候波动造成的径流的变化占3/5~ 4/5, 由于土地覆被变化所造成的径流的变化占1/5.     

北方半干旱区土地利用/覆被变化对湖泊水质的影响:以岱海流域为例(2000—2018年)

土地利用/覆被变化对明晰气候变化和人类活动对湖泊水环境的影响有重要作用.以北方典型农牧交错的岱海流域为研究对象,基于遥感解译技术、马尔可夫转移矩阵、综合污染指数法等方法,对2000-2018年岱海流域土地利用/覆被和湖泊水质的变化进行分析,并结合冗余分析法和计量分析模型探究长时间序列尺度下土地利用/覆被变化对湖泊水质的影响.结果表明:近20年来,岱海流域的土地利用/覆被类型以耕地和草地为主,其变化特征主要是草地和林地转化为耕地,水域转化为季节性河流,岱海转化为内陆滩涂、沼泽草地和灌丛沼泽;岱海湖泊水质因子高锰酸盐指数、五日生化需氧量、总磷和总氮浓度存在不同程度的超标现象;岱海、湿地、林地对水质具有积极的改善作用,耕地、草地、建设用地是加剧水质污染的主要原因.该研究为岱海湖泊流域土地资源合理利用、湖泊水质改善和生态保护提供了一定的科学理论依据.     

基于BTOPMC模型的土地覆被变化径流响应模拟

为分析土地覆被变化的水文效应.构建4种土地覆被情景,采用BTOPMC模型对淮河流域黄泥庄集水区1982-1986年的日径流过程进行模拟.结果表明,土地覆被变化对蒸散发量和径流量计算影响显著,与现状覆被情景的模拟结果相比,森林覆被情景蒸散发量增加,径流量减少,而林地草原和耕地覆被情景下情况相反,且各土地覆被变化情景下枯季径流深的变化幅度明显小于雨季的变化幅度.该模型能较好地分析和评价土地覆被变化下的径流响应.     

太湖流域水文连通性:现状、研究进展与未来挑战

水文连通性作为连接河湖水体间物质、能量及信息传递与交换的关键纽带,对水环境、水生态和生境状况具有联动与触发反馈作用,已成为水文学、水利学和生态学等诸多领域的研究热点.太湖流域作为全国典型的流域性密集平原河网区,在快速城镇化背景下,河湖水文连通关系变化剧烈并引起了一系列生态环境效应.本文以水文连通性概念与内涵为背景,对太湖流域水文连通性研究进行了综述.太湖流域水文连通性评价方法以图论法、景观格局指数及水文连通性函数等方法联合使用为主,且聚焦于区域尺度研究;演变过程按人类活动影响强度大致划分为自然水系形成阶段、古代人类活动影响阶段和现代人类活动影响阶段;气候变化和人类活动共同影响着太湖流域水文连通性变化,近百年来水利工程建设和城市化进程等人类活动的影响尤为剧烈;良好的水文连通性有利于汛期减轻流域洪涝灾害及非汛期保障水资源供给,但水文连通性的提高对水环境和水生态的效应由于涉及因素众多尚存在争议.针对当前研究现状和存在问题,提出(1)平原河网区水文连通性的定量表征与评估是水文连通性研究的前提;(2)定量解析流域水文连通性的驱动机制是水文连通性研究的重点;(3)深入跟踪大型引水调水工程对流域水文连通影响及其效应是一项长期任务;(4)兼顾环境生态效应的水利工程生态化改造研究,开展工程控制背景下的流域水文连通多目标优化调控,是实现太湖流域洪水调蓄、水资源供给、水环境净化、生物多样性维持等生态系统服务协同提升的重要途径.     

太湖流域上游土地利用变化机制的实证分析--以浙江省安吉县为例

近10年来,太湖流域上游地区经济发展逐步趋于活跃,受此影响,区域人口-资源、环境-发展(PRED)出现了新的特点与趋势。基于上游地区土地利用/覆被变化对流域整体水环境与生态安全格局所具有的重要意义,本文选择安吉县作为典型案例,分析其区域土地利用的基本特征,土地利用变化与景观格局动态的过程,以及驱动因素与机制,由此揭示山区土地利用/覆被变化的一般性规律,为太湖流域上游地区经济发展与土地利用、环境保护相互协调,提供决策借鉴与依据。     

中国地表气温变化对土地利用/覆被类型的敏感性

利用观测气温与再分析气温的差值分析了近40年中国地表气温变化对土地利用/覆被类型的敏感性.结果表明：土地利用/覆被类型对地表气温变化具有稳定的、系统性的影响,在全球变暖背景下各类型的响应不同,以沙地、戈壁和裸岩石砾地为主的未利用地升温幅度最大,为0.21℃/10a;其次是草地、耕地和城乡、工矿、居民用地,分别为0.12,0.10,0.12℃/10a;林地升温趋势最弱,为0.06℃/10a.总体来看,沙地、戈壁等未利用地和人类活动较多的区域地表升温幅度大,植被覆盖状况好的区域升温趋势则较弱;同一一级类型下理化特性及生物过程相似的二级类型对地表气温的影响程度相近,土地利用/覆被类型的变化需要达到一定的强度,导致地表特性发生本质改变后才会对局地气温产生较明显的影响;同一土地利用/覆被类型下,中国东部人类活动强度大的区域升温更为明显.这一结果为众多土地利用/覆被变化对气候影响的数值模拟试验研究提供了观测事实的支持.在区域尺度上预测未来中国气候变化不仅要考虑温室气体增加的影响,还要考虑土地利用/覆被类型及其变化的影响.     

太湖流域土地利用变化的水文响应模拟

以城市化快速发展的太湖流域为研究对象,采用1985、1995和2000年TM/ETM土地利用解译资料,应用区域尺度单元格网分布式水文模型,进行长序列水文模拟,定量评估太湖流域土地利用变化及其水文响应特征,为流域用地规划、水资源管理以及灾害防治提供决策参数.研究显示,自1985年到2000年,太湖流域城镇面积扩展了40.38%,增加量占太湖流域总面积的3.88%.在1980-2000年的雨情下,全流域土地利用变化导致产流量平均增加4.11%,约为7.56×108 m3,最高值为11.76%,约为10.0×108 m3.受土地利用变化空间差异影响,产流量增加具有较大区域差异,城镇快速扩展的苏锡常地区和浦东浦西地区,土地利用变化导致产流量平均增加为10.07%和7.03%,最高增量达20%-30%.     

多种对地观测技术及Google Earth技术应用于土地利用/覆被变化建库

为克服传统生态环境监测周期长,可靠性差,精度低的局限性,提出利用多种对地观测技术及Google Earth 技术进行土地利用/覆被变化监测方法.即利用新近获取的遥感影像为信息源,以原有的遥感影像解译数据为基础,对新遥感影像进行土地利用/覆被变化解译,修改旧遥感解译数据库;利用Google Earth上具有的高分辨率遥感影像,在室内对解译过程中的不确定地物进行补判;利用手持GPS接收机在野外对解译结果进行核查,并更新数据库;利用GIS空间分析功能,提取出高精度土地利用/覆被变化信息.实验选取近年旱涝灾害严重的四川作为研究对象,研究结果表明利用多种对地观测技术及Google Earth技术可以有效的对土地利用/覆被变化进行动态监测,并对下一步研究方向进行了探讨.     

Effects of the Land Use and Check Dams on Flood in Upper Catchment of Fuping Hydrological Station by Hydrological Modeling

Flood peaks and volumes had been detected a downward trend in Fuping hydrological station. To quantify the effects of check dams on flood peaks and volumes, a hydrological model integrating land use was established. The model performed well in flood processes simulation, and the Nash efficiency of the model was 0.72. Then the model was used to identify the comprehensive effects of land use and land cover change on flood processes by comparing the simulation results of the selected flood events under 1980 and 2000 land use and land cover conditions. 24.5, 37.7 and 51.3% decrease in flood peaks for flood events of greater than 10 years, 5~10 years and less than 5 years return periods, respectively, and 16.3, 27.9 and 28.5% decrease in flood volumes for the three groups flood events of different return periods. Contributions of land use change and check dams to decrease in flood peak and volume were simulated, and it was found that peak discharge and volume for each flood event responded differently to the two factors. The results in this study can provide valuable information on design flood calculation in the basin under land use and land cover change.     

利用HEC模型分析下垫面变化对洪水的影响——以伊河东湾流域为例

近些年,由于气候变化和人类活动的双重作用改变了流域下垫面的水文特性,探讨研究下垫面变化的水文响应过程具有重要的理论和现实意义.河南伊河洪水虽然量级不大,但发生几率较高,对水库运用和河道冲淤的影响较大.如果洪水变小,伊河下游的造床流量也相应减小,水库控制中常洪水的流量及所需的防洪库容可做相应调整,反之亦然.因此,为了科学...     

Quantifying the impacts of climate change and land use on hydrological processes: A comparison between mountain and lowland agricultural watersheds

Mountain and lowland watersheds are two distinct geographical units with considerably different hydrological processes. Understanding their hydrological processes in the context of future climate change and land use scenarios is important for water resource management. This study investigated hydrological processes and their driving factors and eco-hydrological impacts for these two geographical units in the Xitiaoxi watershed, East China, and quantified their differences through hydrological modelling. Hydrological processes in 24 mountain watersheds and 143 lowland watersheds were simulated based on a raster-based Xin'anjiang model and a Nitrogen Dynamic Polder (NDP) model, respectively. These two models were calibrated and validated with an acceptable performance (Nash-Sutcliffe efficiency coefficients of 0.81 and 0.50, respectively) for simulating discharge for mountain watersheds and water level for lowland watersheds. Then, an Indicators of Hydrological Alteration (IHA) model was used to help quantify the alterations to the hydrological process and their resulting eco-hydrological impacts. Based on the validated models, scenario analysis was conducted to evaluate the impacts of climate and land use changes on the hydrological processes. The simulation results revealed that (a) climate change would cause a larger increase in annual runoff than that under land use scenario in the mountain watersheds, with variations of 19.9 and 10.5% for the 2050s, respectively. (b) Land use change was more responsible for the streamflow increment than climate change in the lowland watersheds, causing an annual runoff to increase by 27.4 and 16.2% for the 2050s, respectively. (c) Land use can enhance the response of streamflow to the climatic variation. (d) The above-mentioned hydrological variations were notable in flood and dry season in the mountain watersheds, and they were significant in rice season in the lowland watersheds. (e) Their resulting degradation of ecological diversity was more susceptible to future climate change in the two watersheds. This study demonstrated that mountain and lowland watersheds showed distinct differences in hydrological processes and their responses to climate and land use changes.     

Response of hydrological processes to land‐cover and climate changes in Kejie watershed,south‐west China

Land‐cover/climate changes and their impacts on hydrological processes are of widespread concern and a great challenge to researchers and policy makers. Kejie Watershed in the Salween River Basin in Yunnan, south‐west China, has been reforested extensively during the past two decades. In terms of climate change, there has been a marked increase in temperature. The impact of these changes on hydrological processes required investigation: hence, this paper assesses aspects of changes in land cover and climate. The response of hydrological processes to land‐cover/climate changes was examined using the Soil and Water Assessment Tool (SWAT) and impacts of single factor, land‐use/climate change on hydrological processes were differentiated. Land‐cover maps revealed extensive reforestation at the expense of grassland, cropland, and barren land. A significant monotonic trend and noticeable changes had occurred in annual temperature over the long term. Long‐term changes in annual rainfall and streamflow were weak; and changes in monthly rainfall (May, June, July, and September) were apparent. Hydrological simulations showed that the impact of climate change on surface water, baseflow, and streamflow was offset by the impact of land‐cover change. Seasonal variation in streamflow was influenced by seasonal variation in rainfall. The earlier onset of monsoon and the variability of rainfall resulted in extreme monthly streamflow. Land‐cover change played a dominant role in mean annual values; seasonal variation in surface water and streamflow was influenced mainly by seasonal variation in rainfall; and land‐cover change played a regulating role in this. Surface water is more sensitive to land‐cover change and climate change: an increase in surface water in September and May due to increased rainfall was offset by a decrease in surface water due to land‐cover change. A decrease in baseflow caused by changes in rainfall and temperature was offset by an increase in baseflow due to land‐cover change. Copyright © 2009 John Wiley & Sons, Ltd.     

Reviews on land use change induced effects on regional hydrological ecosystem services for integrated water resources management

This paper proposed to provide valuable information for integrated water resources management through evaluating the research on the interaction mechanism among land use changes, regional hydrological ecosystem services and human well-being. Firstly, the driving mechanism of land use and land cover changes was introduced in this paper. Secondly, the overview of the interaction mechanism among land use and land cover changes, regional hydrological ecosystem services and human well-being was given. Based on the meta-analysis, land use changes have a profound influence on regional hydrological ecosystem services, and the variation of hydrological ecosystem could benefit or impair human well-being. Finally, two suggestions were emphasized for managers or policy makers for the future integrated water resources management: (1) Proper land use makes for the water resource management; (2) Blindly pursuing the provisioning services weakens other services of hydrological ecosystem.     

Modelling and assessment of hydrological changes in a developing urban catchment

Urbanization strongly changes natural catchment by increasing impervious coverage and by creating a need for efficient drainage systems. Such land cover changes lead to more rapid hydrological response to storms and change distribution of peak and low flows. This study aims to explore and assess how gradual hydrological changes occur during urban development from rural area to a medium‐density residential catchment. The Stormwater Management Model (SWMM) is utilized to simulate a series of scenarios in a same developing urban catchment. Sub‐hourly hydro‐meteorological data in warm season is used to calibrate and validate the model in the fully developed catchment in 2006. The validated model is then applied to other cases in development stage and runoff management scenarios. Based on the simulations and observations, three key problems are solved: (1) how catchment hydrology changes with land cover change, (2) how urban development changes pre‐development flows, and (3) how stormwater management techniques affect catchment hydrology. The results show that the low‐frequency flow rates had remarkably increased from 2004 to 2006 along with the increase of impervious areas. Urbanization in the residential catchment expands the runoff contributing area, accelerates hydrological response, raises peak flows in an order of magnitude of over 10, and more than doubles the total runoff volume. The effects of several LID controls on runoff hydrograph were simulated, and the techniques were able to reduce flows towards the pre‐development levels. However, the partly restored flow regime was still clearly changed in comparison to the pre‐development flow conditions. Copyright © 2014 John Wiley & Sons, Ltd.     

Assessing the effects of land cover and future climate conditions on the provision of hydrological services in a medium‐sized watershed of Portugal

The separated and combined effects of land‐cover scenarios and future climate on the provision of hydrological services were evaluated in Vez watershed, northern Portugal. Soil and Water Assessment Tool was calibrated against daily discharge, sediments and nitrates, with good agreements between model predictions and field observations. Four hypothetical land‐cover scenarios were applied under current climate conditions (eucalyptus/pine, oak, agriculture/vine and low vegetation). A statistical downscaling of four General Circulation Models, bias‐corrected with ground observations, was carried out for 2021–2040 and 2041–2060, using representative concentration pathway 4.5 scenario. Also, the combined effects of future climate conditions were evaluated under eucalyptus/pine and agriculture/vine scenario. Results for land cover revealed that eucalyptus/pine scenario reduced by 7% the annual water quantity and up to 17% in the summer period. Although climate change has only a modest effect on the reduction of the total annual discharge (?7%), the effect on the water levels during summer was more pronounced, between ?15% and ?38%. This study shows that climate change can affect the provision of hydrological services by reducing dry season flows and by increasing flood risks during the wet months. Regarding the combined effects, future climate may reduce the low flows, which can be aggravated with eucalyptus/pine scenario. In turn, peak flows and soil erosion can be offset. Future climate may increase soil erosion and nitrate concentration, which can be aggravated with agriculture scenario. Results moreover emphasize the need to consider both climate and land‐cover impacts in adaptation and land management options at the watershed scale. Copyright © 2015 John Wiley & Sons, Ltd.     

Impact of land-use change on hydrological processes in the Maying River basin, China

Since the 1960s, dramatic changes have taken place in land-use patterns characterized by the persistent expansion of cultivated land and a continuous decrease in natural woodland and grassland in the arid inland river basins of China. It is very important to assess the effects of such land-use changes on the hydrological processes so vital for water resource management and sustainable development on the catchment scale. The Maying River catchment, a typical arid inland watershed located in the middle of the Hexi Corridor in northwest China, was the site chosen to investigate the hydrological responses to land-use changes. The annual runoff, base flow, maximum peak flow, and typical seasonal runoff in both spring and autumn flood periods were selected as the variables in the hydrological processes. Statistical-trend analysis and curvilinear regression were utilized to detect the trends in hydrological variables while eliminating the climatic influence. The relationship between cultivated land-use and hydrological variables was analyzed based on four periods of land-use variation data collected since 1965. A runoff model was established composed of two factors, i.e., cultivated land use and precipitation. The impact of land use changes, especially in the large ar- eas of upstream woodland and grassland turned into cultivated lands since 1967, has resulted in a mean annual runoff decrease of 28.12%, a base flow decline of 35.32%, a drop in the maximum peak discharge of 35.77%, and mean discharge decreases in spring and autumn of 36.05% and 24.87% respectively, of which the contribution of cultivated land expansion to the influence of annual runoff amounts to 77%-80%, with the contribution to the influence of spring discharge being 73%-81%, and that to the influence of base flow reaching 62%-65%. Thus, a rational regulation policy of land use patterns is vitally important to the sustainable use of water resources and the proper development of the entire catchment.     

Development of distributed time-variant gain model for nonlinear hydrological systems

Hydrological science is a branch of the earth sci-ences.To study the complexities of hydrological pro-cesses and the associated environmental problems,a systematic approach is desired.For instance,Dooge published Linear Theory of Hydrological System[1]in1973.Singh(1988)published Hydrological Systems[2],with its Chinese version[3]being translated by the Yel-low River Conservancy Commission in2000.Ge(1999)carried out systematic studies on the hydro-logical linear system theory,and produced …