耦合水库群参数化方案的区域陆面水文模拟

中国水库数目众多,密集的水库运行和调蓄影响着陆地水循环和陆气间的水分能量交换过程,给高强度开发地区水文规律认知和水文模拟及预报带来了挑战。围绕这一问题,本研究以鄱阳湖流域及流域内千余座水库为研究对象,从水库水量平衡方程、水库蓄泄规则、多阻断扩散波汇流等方面构建了水库群参数化方案,并从地表水、地下水、蒸散发、能量通量等角度实现了其与陆面水文双向耦合模式（CLHMS）的动态耦合。结果表明:所构建的水库群参数化方案可以较好地模拟水库的蓄泄过程,提高了耦合模式在鄱阳湖流域的径流模拟精度;水库群可以使赣江、信江、抚河丰水期径流减少3.7%~6.0%,枯水期径流增加5.9%~12.6%,多年平均径流减少0.6%~1.5%;在空间分布上,水库群对流域中部和北部径流的调蓄作用相对显著。本研究所改进的陆面水文模式可以为高强度人类活动影响下气象、水文、水资源交叉领域的研究提供分析工具和模型基础,从而支撑变化环境下区域水资源的可持续利用。     

黄淮海平原地区“三水”转化水文模型

根据黄淮海平原地区地下水较浅,地表水、土壤水和地下水三者之间有密切联系的特点,本文提出了一个以水循环各要素为基础,并考虑三水转化关系的水文模型。只要根据流域自然特性确定了模型的参数,输入降水量和水面蒸发量资料,即可求出次产流量、陆面蒸发量和地下水变化过程。用2个小流域资料进行验证,拟合情况良好。     

人类用水活动对大尺度陆地水循环的影响

随着人口增长和经济社会快速发展,人类活动已成为陆地水循环变化的重要驱动因子,人类用水活动对陆地水循环的影响越来越受到人们的关注。回顾近年来人类用水活动对大尺度陆地水循环影响方面的研究进展;阐述灌溉、生活和工业用水、水库调节以及地下水利用等典型人类用水活动影响大尺度陆地水循环的过程与机制,并在此基础上探讨了陆面水文模型中人类用水活动参数化方案及其存在的问题。目前,陆面水文模型对人类用水活动的考虑依然不足,使得应用模型模拟陆地水循环和评估变化环境下水资源安全面临挑战。展望未来,深入认识人类用水活动与水系统的影响与反馈,开发考虑人—水系统协同演化的水系统综合评估模型,预估水安全形势的演变趋势,将成为陆地水循环和水资源研究的长期重要任务。     

促进相关学科之间的渗透，深入开展气候变化对水资源影响的研究

说明了水资源研究的两大方向,重点就气候变化对水资源影响的研究,提出了建议:1、利用遥感技术完善水资源评价工作;2、研究各流域年径流变化与气候因子间的统计关系;3、进一步弄清我国水循环图象及其在欧亚大陆整个水循环中的作用和相互联系;4、研究气候变化对大气水转换成地表水及土壤水过程中的作用;5、建立大气环流模型与水文模型相耦合的系统并联合进行数值模拟试验。     

陆地水循环过程的综合集成与模拟

在气候变化与人类活动的影响下,陆地水循环过程发生了明显改变,并导致了一系列资源环境问题。深入认识陆地水循环过程的变化机理,发展陆地水循环过程综合集成模拟技术,预估未来陆地水循环的变化趋势,是当前水循环研究面临的重要任务。主要关注人类活动影响下的大尺度(大河流域或大陆尺度)陆地表层系统水循环模拟,梳理了近年来陆地水循环过程综合集成与模拟相关的研究进展,指出当前大尺度陆地表层系统水循环模拟模型的主要问题是对自然过程与人类活动过程间相互作用描述不足,以及人类活动参数化方案的不完善。因此,完善人类活动参数化方案,构建陆地水循环过程的综合集成模型,是模拟研究的重要发展方向之一。同时,考虑多要素过程的综合集成模型有助于解释气候变化与人类用水活动影响水循环变化的关键机制,为探索变化环境下陆地水循环变化成因及其效应提供理论与实践基础,其结果将为区域水资源配置及应对全球变化的战略决策提供科学依据。     

长江流域地下水资源特征与开发利用现状

提要:为提升对长江流域水文地质和地下水资源的认知程度,突破以往单独从地表水或地下水角度进行评价的局限性,长江流域水文地质调查工程以地球系统科学理论和水循环理论为指导,充分考虑地表水与地下水的转化关系,将水文地质单元和地表水流域有机结合,划分长江流域地下水评价单元,建立典型地下水资源评价模型,开展了新一轮长江流域地下水资...     

基于GSFLOW的镜湖湿地地表水与地下水耦合数值模拟

湿地地表径流包括明渠流和片流等多种形式,且存在海绵状土壤层,其地表水-地下水耦合模拟困难。针对湿地片流和海绵层模拟不准确的问题,以绍兴镜湖国家城市湿地公园为研究对象,考虑湿地多年植物生长沉积形成的独特海绵层,基于GSFLOW模型构建湿地地表水与地下水耦合数值模型,通过二维扩散方程模拟湿地片流、一维圣维南方程模拟湿地明渠流,使用竖管法测量湿地海绵层渗透系数,利用模拟区水文站的监测数据率定模型参数并对模拟结果进行验证,应用校正后模型模拟湿地地表水与地下水的水量交互过程,并对研究区进行水均衡分析。研究结果表明:考虑湿地海绵层的湿地地表水与地下水耦合模型能较为真实地反映湿地水文特性,湿地以地表水补给地下水为主,补给量随降雨量变化。研究建立的湿地地表水与地下水耦合模型合理可靠,对湿地水文分析有良好的应用价值。     

考虑地表-地下水相互作用的地下水流动研究

地下水是水文系统的重要组成部分,对保护和开发日益枯竭的水资源具有重要的战略意义。地下水作为一种自然资源,对供水和水质起着至关重要的作用。地下水模拟是水资源可持续管理的重要组成部分。因此,地下水的物理机制应该通过建立详细的水文和污染物运移模型来确定。此外,为了建立准确的地下水模型,应考虑地表-地下水相互作用。虽然许多研究将地下水作为一个单一系统,研究地下水水力学和水文学,但通过在不同情况下进行敏感性分析来研究地表水-地下水相互作用和地下水行为的研究很少。因此,本文将地表水和地下水视为一个独立的系统,并进行相应的模拟。本研究利用三维有限差分法地下水流动与污染物运移模拟模型,建立了一个概化的河流-含水层模型。研究了地表水与地下水相互作用对水文特性的影响。利用概化河流-含水层系统的水文模型,在不同的水流边界条件和水流路径下进行分析,得到地下水位波动和河流与含水层之间的流量。     

概念性岩溶水文模型中几个疑难问题的探讨

由于岩溶地下水分布难以量测,岩溶水文系统多为黑箱或灰箱,采用岩溶水文模型量化其水循环过程常存在许多疑难问题。本文侧重讨论岩溶水循环中产流与汇流、岩溶区流域面积确定、地表水与地下水划分、以及解决这些问题的技术方法。并对观行的概念性水文模型结构功能及存在问题进行了分析。      

珠江流域大尺度陆面水文耦合模式的构建及应用

以珠江流域为研究对象,通过更新陆面水文模式所需的下垫面参数数据库,建立适合于珠江流域的大尺度陆面水文耦合模式系统,并利用该模式开展了1963~2006年流域水文水循环过程的数值模拟,通过与实测流量比较,系统考察了陆面水文耦合模型对珠江流域水循环各分量的模拟性能。分析结果表明,该陆面水文耦合模式对珠江流域年平均各水循环要素具有良好的模拟能力;模式对珠江流域干流主要控制水文站的月平均流量也有较高的模拟精度,模式模拟的水量平衡系数均接近1,相关系数均高于0.84,IOA相似度系数均高于0.9;相对而言,模式对流量峰值的模拟能力还有待提高。     

气候变化对陆地水循环影响研究的问题

简要地回顾了现存的由气候情景驱动水文模型研究气候变化对陆地水循环影响的方法。指出这种单向连接方法很难将气候变暖及人类活动引起的陆地水循环变化反馈给大气。这既影响对降雨的预测精度,又不能正确地描写陆地水循环的变化。近10年来气候学家对大气环流模型中陆面过程模型的改进以及水文气候学家对大尺度水文模型研究所取得的进展,展现了它们之间的互补性,以及未来用水文-气候耦合模型方法研究气候变化与人类活动对陆地水循环影响及水资源预测的可能性。     

An experimental investigation to characterise soil macroporosity under different land use and land covers of northeast India

Saturated macropore flow is the dominant hydrological process in tropical and subtropical hilly watersheds of northeast India. The process of infiltration into saturated macroporous soils is primarily controlled by size, network, density, connectivity, saturation of surrounding soil matrix, and depthwise distribution of macropores. To understand the effects of local land use, land cover and management practices on soil macroporosity, colour dye infiltration experiments were conducted with ten soil columns (25 × 25 × 50 cm) collected from different watersheds of the region under similar soil and agro-climatic zones. The sampling sites included two undisturbed forested hillslopes, two conventionally cultivated paddy fields, two forest lands abandoned after Jhum cultivation, and two paddy fields, one pineapple plot and one banana plot presently under active cultivation stage of the Jhum cycle. Digital image analyses of the obtained dye patterns showed that the infiltration patterns differed significantly for different sites with varying land use, land cover, and cultivation practices. Undisturbed forest soils showed high degree of soil macroporosity throughout the soil profile, paddy fields revealed sealing of macropores at the topsoil due to hard pan formation, and Jhum cultivated plots showed disconnected subsoil macropores. The important parameters related to soil macropores such as maximum and average size of macropores, number of active macropores, and depthwise distribution of macropores were estimated to characterise the soil macroporosity for the sites. These experimentally derived quantitative data of soil macroporosity can have wide range of applications in the region such as water quality monitoring and groundwater pollution assessment due to preferential leaching of solutes and pesticides, study of soil structural properties and infiltration behaviour of soils, investigation of flash floods in rivers, and hydrological modelling of the watersheds.     

干旱区平原绿洲散耗型水文模型——Ⅰ模型结构

针对干旱地区平原绿洲水土资源利用的特点,建立了以农区土壤水为中心的干旱区平原绿洲散耗型水文模型。散耗型模型考虑了水在不同介质和不同形态之间的交换或转化,并重点考虑人类活动如引水灌溉、地下水的开采等对水平衡的影响。模型把研究区划分为河段、泉井、水库湖泊、农区和非农区五类水均衡模块,水均衡模块之间通过地表渠系、地下水侧渗进行水量交换。应用模型可以对研究区农区、非农区各自的蒸发量、农区向非农区地下水迁移量等干旱区主要水分散耗项进行分析。     

干旱区平原绿洲散耗型水文模型——Ⅰ模型结构

针对干旱地区平原绿洲水土资源利用的特点,建立了以农区土壤水为中心的干旱区平原绿洲散耗型水文模型。散耗型模型考虑了水在不同介质和不同形态之间的交换或转化,并重点考虑人类活动如引水灌溉、地下水的开采等对水平衡的影响。模型把研究区划分为河段、泉井、水库湖泊、农区和非农区五类水均衡模块,水均衡模块之间通过地表渠系、地下水侧渗进行水量交换。应用模型可以对研究区农区、非农区各自的蒸发量、农区向非农区地下水迁移量等干旱区主要水分散耗项进行分析。     

河套灌区井渠联合运用优化灌溉模型

针对河套灌区的地面水与地下水联合运用问题,提出了井渠结合优化灌溉模型,以最佳种植模式和最优工程运行策略,达到控制地下水位、防治土壤盐碱化、获得农作物稳产高产的目的.模型有调蓄地面水源、土壤贮水层、地下含水层的能力.优化计算成果与266.7hm2试验示范区的实际运行结果相吻合,节水、节能、增产及控制地下水位、改良盐碱地等效果十分显著,这对发展节水型灌溉农业具有重要的现实意义.     

Soil water-salt dynamics state and associated sensitivity factors in an irrigation district of the loess area: a case study in the Luohui Canal Irrigation District,China

Soil salinisation determines the distribution pattern of crop processes in irrigation districts. The research presented here was conducted in the Luohui Canal Irrigation District, which is located in the loess area of Shaanxi Province, China. A back-propagation artificial neural network (BPANN) for the soil water-salt state was established to predict soil salinity and alkalinity. The degree of influence of numerous factors on the dynamics was quantitatively determined using the default factor testing method and verified with grey relational analysis. The results show that the BPANN prediction accuracy is very high, and it can efficiently depict the comprehensive relationships between the influential factors and dynamic states. The influence of soil moisture, evaporation, groundwater salt and groundwater depth on the dynamics is significant in the region. The current irrigation method, used for many years, cannot meet the water necessities for the vegetation, causing the groundwater levels to decline and a lowering of the soil moisture zone, leading to the occurrence of serious soil salinisation. Under the action of evaporation, more salt accumulates in the upper part of the soil, resulting in extensive soil salinisation. The higher the groundwater salt content, the more salt is carried by rising capillary water, and the more the soil is salinised. If groundwater depth was to exceed the critical water table, then groundwater and salt would move to the soil surface by moisture evaporation, and salt would build up on the soil surface in this irrigation district. The interactions between each factor forms a complex coupling relationship state.     

Water resources development and management in the Cuddapah district, India

 Intensive application of surface water in command areas of irrigation projects is creating water logging problems, and the increase of groundwater usage in agriculture, industry and domestic purposes (through indiscriminate sinking of wells) is causing continuous depletion of water levels, drying up of wells and quality problems. Thus the protect aquifers to yield water continuously at economical cost, the management of water resources is essential. Integrated geological, hydrological (surface and groundwater) and geochemical aspects have been studied for the development and management of water resources in drought-prone Cuddapah district. The main lithological units are crystallines, quartzites, shales and limestones. About 91 000 ha of land in the Cuddapah district is irrigated by canal water. A registered ayacut of about 47 000 ha is irrigated by 1368 minor irrigation tanks. A total of 503 spring channels are identified in the entire district originating from the rivers/streams, which has the capacity of irrigating about 8700 ha. The average seasonal rise in groundwater level is 7.32 m in quartzites, 5.35 m in crystallines, 3.82 m in shales, 2.50 m in limestones and 2.11 m in alluvium. Large quantities of groundwater are available in the mining areas which can be utilised and managed properly by the irrigation department/cultivators for the irrigation practices. Groundwater assessment studies revealed that 584 million m³ of groundwater is available for future irrigation in the district. From the chemical analysis, the quality of groundwater in various rock units is within the permissible limits for irrigation and domestic purposes, but at a few places the specific conductance, chloride and fluoride contents are high. This may be due to untreated effluents, improper drainage system and/or the application of fertilisers. Received: 10 June 1998 · Accepted: 15 November 1998     

Impacts of Human Water Use on the Large-scale Terrestrial Water Cycle

Along with the increase of population and extraordinary economic and social development, human appropriation of freshwater supply increases rapidly. Anthropogenic activities have become an important driving factor of the large-scale terrestrial water cycle. The hydrological effects of human water use have attracted growing attention. In this paper, we briefly reviewed the recent studies addressing the anthropogenic disturbance of the large-scale terrestrial water cycle. The review focused on the direct alteration of the water cycle for human needs, with special coverage for the primary aspects of human water use such as irrigation, domestic and industrial water use, reservoir regulation and groundwater mining. The state-of-the-art parameterization schemes of human water use for macroscale land surface hydrological modeling were introduced and the limitations of the schemes were discussed. Considering the impacts of human water use on the terrestrial water cycle is currently a challenge for macroscale land surface hydrological modeling, which hinders the use of the models in assessing water resources under changing environment. Further studies are needed to understand the interactions between human and water systems, to develop integrated assessment model of coupled human-water systems, and to assess regional and global water security.     

基于生态圈层结构稳定的地下水位计算与调控

干旱区绿洲灌区水资源集中开发使用,改变了地下水潜流场分布,造成了盐渍化和荒漠化并存的生态问题,严重威胁着绿洲的生态安全。以生态圈层结构理论为基础,深化研究潜水影响层概念内涵,构建干旱平原区潜水蒸发概念性模型,以黑河罗城灌区为例,从机理上揭示干旱区荒漠化与盐渍化的地下水埋深条件并进行定量计算与调控,主要成果如下:①描述了造成内陆河干旱区绿洲内部盐渍化和过渡带荒漠化的潜水蒸发运移规律,利用潜水影响层定义了盐渍化与荒漠化地下水临界埋深,并进行了定量计算,得到罗城灌区绿洲内部次生盐渍化的地下水临界埋深为1.3~1.5 m,过渡带荒漠化地下水临界埋深为8~13 m;②讨论了潜水影响层厚度定量公式中关键参数土壤当量孔径和液体表面张力在不同生态问题中的合理取值;③提出一种协同缓解干旱区盐渍化和荒漠化的地下水位调控方案,实现改善灌区内部盐渍化、控制过渡带荒漠化和水资源高效利用等多个目标。     

灌区水资源合理配置研究进展

灌区水资源合理配置是提高灌区水资源利用效率及保障粮食安全的重要途径,也是实现灌区水资源可持续利用的有效调控措施。从灌区水资源管理政策、水资源循环转化规律、水资源优化配置模型与方法和水文生态4个方面,对国内外该领域的研究现状进行了对比分析。研究发现,国内灌区水资源配置主要存在4个方面的问题:水资源合理配置与保护政策落实不到位、水资源的统一管理机制不健全、水资源优化配置模型实用性不强和水资源优化配置基础条件较为薄弱。建议加强灌区水资源的统一管理政策与机制、变化环境下水资源循环转化规律、水资源承载力基础理论与评价新方法、水文生态调控技术、水资源实时风险调度与智能化管理技术以及水资源优化配置耦合技术研究。