流域水文模型研究进展

本文介绍了流域水文模型的分类,论述了流域水文模型基础理论——产汇流理论的发展及其自身的研究进展,探讨了流域水文模型的研究趋势和发展困境,并对未来做出了展望,以期能推进流域水文模型的研究。     

甘肃西北部黑河流域水资源对下游生态环境变化的影响阈

从流域尺度水资源承载能力及其有限性、可变性和上下游关联性的角度,探讨了黑河流域下游区生态环境变化的影响阈,阐明了不同水文年中游区的安全引水量和不同目标下下游区的生态环境修复对水资源的需求阈.基于多年平均地表径流量37.8×108m3/a的安全引水量为13.97×108m3/a和枯水年份(95%保证率)的安全引水量为10.14×108m3/a,下游区初步改善生态环境的生态需水量为8.01×108m3/a.提出了中游区经济社会可持续发展的水资源保障阈,即未来20年生产生活安全需水量介于22×108～23×108m3/a之间.在此基础上,阐明了在中游区经济社会稳定持续发展目标约束下确保黑河流域下游区生态环境不断改善的流域水资源优化配置模式及对策.     

岩溶断陷盆地不同海拔植物水分利用效率分析

为探讨不同海拔高度的养分、环境要素与植物水分利用效率变化的关系，以岩溶断陷盆地云南小江流域的乔木、灌木、草本为研究对象，分析水分利用效率和叶片养分浓度随海拔的变化情况。结果表明:（1）研究区内海拔2 000 m处的草本植物的叶片δ13C值最高，2 200 m处的乔木的叶片δ13C值最低；（2）海拔高度对乔木、灌木的植物水分利用效率影响大于草本植物，草本植物的水分利用效率随海拔高度的变化甚微，两者之间的拟合度较小；高值区出现在海拔为2 200 m处的乔木；低值区出现在海拔为2 000 m处的草本植物；（3）不同海拔水分利用效率与叶片N、P浓度的相关性较弱（与叶片的N浓度呈弱正相关，与叶片的P浓度呈弱负相关）；（4）不同海拔水分利用效率与各气候因子的相关性较弱，与多年平均气温、多年平均降雨量、多年平均日照时数均呈弱正相关。      

Delineation of potential groundwater zones based on multicriteria decision making technique

Groundwater is the most prioritized water source in India and plays an indispensable role in India's economy. The groundwater potential mapping is key to the sustainable groundwater development and management. A hybrid methodology is applied to delineate potential groundwater zones based on remote sensing, geographical information systems(GIS) and analytic hierarchy process(AHP) as on multicriteria decision making. For the purpose of demonstrating field application, Chittar watershed, Tamilnadu, India is studied as an example. The important morphological characteristics considered in the study are lithology, geomorphology, lineament density, drainage density, slope, and Soil Conservation Service–Curve Number(SCS-CN). These six thematic layers are generated in a GIS platform. Based on intersecting the layers, AHP method, the values for adopting the pairwise comparison normalized weight and normalized subclasses weightage were given. The normalized subclass weightage is input into each layer subclass. Then, weighted linear combination method is used to add the data layers in GIS platform to generate groundwater potential Index(GWPI) map. The GWPI map is validated based on the net recharge computed from the differences of measured groundwater levels between the pre-monsoon and post-monsoon in the year 2018. The kappa statistics are used to measure level spatial consistency between the GWPI and net recharge map. The overall average spatial matching accuracy between the two data sets is 0.86, while the kappa coefficient for GWPI with net recharge, 0.78. The results show that in Chittar watershed about 870 km~2 area is divided into high potential zone(i.e. sum of very high and high potential zone), 667 km~2 area, as the moderate one and the rest 105 km~2 area, as the poor zone(i.e. sum of very poor and poor potential zone).     

黑河下游额济纳绿洲环境退化及综合治理＊

黑河下游的额济纳绿洲是内蒙西部阿拉善高原的主要天然绿洲。近半个世纪特别是近１０年来,由于不合理人类活动和自然因素的双重作用,黑河下泄水量不断减少,生态环境恶化,严重影响到本地区乃至周围广大地区的持续发展。通过分析生态环境恶化的现状和原因,提出了生态环境的治理必须以水为中心,加快中游地区节水农业的发展步伐,保证下游一定量的供水,并严格控制不合理的人为活动,力争在１０～１５年内实现生态环境的良性循环。     

陕西神府矿区束鸡沟流域风蚀水蚀交互作用特征研究

以神府矿区束鸡沟为典型小流域,讨论了风蚀水蚀交互作用的时空分布及其特征。风蚀水蚀交互作用在沙质坡面,坡面切沟和沙质沟道区表现最为突出,并形成了风蚀水蚀交互作用特有的侵蚀形态。     

PHYSICAL PROCESS BASED SOIL EROSION MODEL IN A SMALL WATERSHED IN THE HILLY LOESS REGION

ＰＨＹＳＩＣＡＬＰＲＯＣＥＳＳＢＡＳＥＤＳＯＩＬＥＲＯＳＩＯＮＭＯＤＥＬＩＮＡＳＭＡＬＬＷＡＴＥＲＳＨＥＤＩＮＴＨＥＨＩＬＬＹＬＯＥＳＳＲＥＧＩＯＮ１ＣＡＩＱｉａｎｇｇｕｏ２ＡＢＳＴＲＡＣＴＡｐｈｙｓｉｃａｌｐｒｏｃｅｓｂａｓｅｄｐｅｒｓｔｏｒｍ...     

Spatial scale effect on seasonal streamflows in permafrost catchments on the Qinghai–Tibet Plateau

The scale issue is of central concern in hydrological processes to understand the potential upscaling or downscaling methodologies, and to develop models for scaling the dominant processes at different scales and in different environments. In this study, a typical permafrost watershed in the Qinghai‐Tibet Plateau was selected. Its hydrological processes were monitored for 4 years from 2004 to 2008, measuring the effects of freezing and thawing depth of active soil layers on runoff processes. To identify the nature and cause of variation in the runoff response in different size catchments, catchments ranging from 1·07 to 112 km² were identified in the watershed. The results indicated that the variation of runoff coefficients showed a ‘V’ shape with increasing catchment size during the spring and autumn seasons, when the active soil was subjected to thawing or freezing processes. A two‐stage method was proposed to create runoff scaling models to indicate the effects of scale on runoff processes. In summer, the scaling transition model followed an exponential function for mean daily discharge, whereas the scaling model for flood flow exhibited a linear function. In autumn, the runoff process transition across multiple scales followed an exponential function with air temperature as the driving factor. These scaling models demonstrate relatively high simulation efficiency and precision, and provide a practical way for upscaling or downscaling runoff processes in a medium‐size permafrost watershed. For permafrost catchments of this scale, the results show that the synergistic effect of scale and vegetation cover is an important driving factor in the runoff response. Copyright © 2011 John Wiley & Sons, Ltd.     

Rainfall,runoff and shallow groundwater response in a mixed-use,agro-forested watershed of the northeast,USA

Stream and shallow groundwater responses to rainfall are characterized by high spatial variability, but hydrologic response variability across small, agro-forested sub-catchments remains poorly understood. Conceivably, improved understanding in this regard will result in agricultural practices that more effectively limit nutrient runoff, erosion, and pollutant transport. Terrestrial hydrologic response approaches can provide valuable information on stream-aquifer connectivity in these mixed-use watersheds. A study was implemented, including eight stream and co-located shallow groundwater monitoring sites, in a small sub-catchment of the Chesapeake Bay watershed in the Northeast, USA to advance this ongoing need. During the study period, 100 precipitation-receiving days (i.e., 24-hour periods, midnight to midnight) were observed. On average, the groundwater table responded more to precipitation than stream stage (level change of 0.03 vs. 0.01 m and rainfall-normalized level change estimate of 3.81 vs. 3.37). Median stream stage responses, groundwater table responses, and response ratios were significantly different between sub-catchments (n = 8; p < 0.001). Study area average precipitation thresholds for runoff and shallow groundwater flow were 2.8 and 0.6 cm, respectively. Individual sub-catchment thresholds ranged from 0.5 to 2.8 cm for runoff and 0.2 to 1.3 cm for shallow groundwater flow. Normalized response lag times between the stream and shallow groundwater ranged from −0.50 to 3.90 s·cm⁻¹, indicating that stormflow in one stream section was regulated by groundwater flow during the period of study. The observed differences in hydrologic responses to precipitation advance future modelling efforts by providing examples of how terrestrial groundwater response methods can be used to investigate sub-catchment spatial variability in stream-aquifer gradients with co-located shallow groundwater and stream stage data. Additionally, results demonstrate asynchronous stream and shallow groundwater responses on precipitation-receiving days, which may hold important implications for modelling hydrologic and biogeochemical fate and transport processes in small, agro-forested catchments.