开都河天山出山径流量年际变化特征与洪水频率分析

随着塔里木河流域近期综合治理的深入进行,其源流之一开都河径流的变化与其趋势已逐渐成为国内外科学家关注的热点问题。当前塔里木河干流下游的生态恢复在较大程度上依赖开都河,利用开都河丰水期向塔河下游进行应急输水的方式短期是可行的,长期实施则潜伏着危机。如果在开都河进入水文枯水期时进行输水,则不仅影响开都河流域的生态环境,还将影响塔河下游“绿色走廊”治理目标的实现。因此,根据开都河近50年水文资料,利用滑动平均、频率分析等方法,分析了开都河径流量、洪峰流量的年际变化特征和规律。结果表明:开都河丰枯水期变化较平稳,1987年后其出径流量呈增加的趋势。同时,还计算出了不同重现期的洪峰设计值。     

长江干流日径流序列的多重分形特征

基于长江干流寸滩、宜昌和大通三个主要控制水文站多年的日径流资料,运用多重分形消除趋势波动分析 (MF-DFA)等方法,识别长江流域不同空间尺度上径流序列的多重分形特征,并采用推广的乘积阶次模型,对多重分形谱进行拟合。结果表明: (1)长江干流的日径流序列具有自相似的多重分形特征,该多重分形特征是由序列内在的长程相关性引起的;(2)长江干流日径流序列的多重分形谱可用推广的乘积阶次模型进行描述,模型拟合的参数a、b可作为该水文站点的特征参数,能够对降雨径流模型有效地进行检测;(3)长江干流日径流变化的复杂程度具有空间差异性。下游大通水文站径流序列的奇异性大于上游两站点,其径流变化过程更为复杂,而上游两站奇异性相差不大。造成三个站点径流过程变化复杂程度差异的主要原因,包括集水面积、来水组成、降水特点和下垫面状况等。     

Synchronism of runoff response to climate change in Kaidu River Basin in Xinjiang, Northwest China

The runoff in alpine river basins where the runoff is formed in nearby mountainous areas is mainly affected by temperature and precipitation.Based on observed annual mean temperature,annual precipitation,and runoff time-series datasets during 1958–2012 within the Kaidu River Basin,the synchronism of runoff response to climate change was analyzed and identified by applying several classic methods,including standardization methods,Kendall's W test,the sequential version of the Mann-Kendall test,wavelet power spectrum analysis,and the rescaled range(R/S) approach.The concordance of the nonlinear trend variations of the annual mean temperature,annual precipitation,and runoff was tested significantly at the 0.05 level by Kendall's W method.The sequential version of the Mann-Kendall test revealed that abrupt changes in annual runoff were synchronous with those of annual mean temperature.The periodic characteristics of annual runoff were mainly consistent with annual precipitation,having synchronous 3-year significant periods and the same 6-year,10-year,and 38-year quasi-periodicities.While the periodic characteristics of annual runoff in the Kaidu River Basin tracked well with those of annual precipitation,the abrupt changes in annual runoff were synchronous with the annual mean temperature,which directly drives glacier-and snow-melt processes.R/S analysis indicated that the annual mean temperature,annual precipitation,and runoff will continue to increase and remain synchronously persistent in the future.This work can improve the understanding of runoff response to regional climate change to provide a viable reference in the management of water resources in the Kaidu River Basin,a regional sustainable socio-economic development.     

开都河流域上下游过去50 a气温降水变化特征分析

利用开都河流域上下游4个气象台站（上游巴音布鲁克,下游焉耆、和静、和硕）1960-2009年的气温、降水资料,采用趋势分析与距平等统计方法,分析了近50 a来开都河流域的主要气象要素变化特征。研究发现：（1）1960-2009年开都河流域上下游年平均气温均呈明显上升趋势,增长强度分别为0.27 ℃/10 a和0.22 ℃/10 a。2000年后气温升高尤其显著,上游和下游的气温分别较50 a平均水平偏高0.97 ℃和0.69 ℃。该流域年最高温没有明显增加,而上下游年最低气温分别上升0.41 ℃/10 a和0.61 ℃/10 a,并与年平均气温有较好的相关性。通过对不同年代际各月气温的分析,发现该地区气温季节性特征在过去50 a发生了明显的变化。主要表现为冬季气温总体上升,夏季气温相对稳定,冬季与夏季温差逐渐减小,季节性呈变弱趋势。上游年代际间气温季节变化较下游更明显;（2）开都河流域降水主要集中在夏季,近50 a上下游降水量均呈增加趋势且上游达显著水平。上下游在降水分布及变化特征上有较大差异,上游年平均降水总量（273 mm）明显高于下游（77 mm）,且上游降水量增加强度（9.13 mm/10 a）高于下游（5.34 mm/10 a）。降水量年代际之间有一定差异,降水波动主要是在夏季,上游降水量的波动性大于下游。     

开都河流域气候变化对地表水的影响

1IntroductionWetlands, forests and oceans are the three main ecosystems with the highest ecological values in the world. According to the data of United Nations Environment Programme in 2002, the annual production value of the wetland ecosystems per hecta…     

Impacts of climate change and agricultural activities on water quality in the Lower Kaidu River Basin,China

In the context of climate change and over-exploitation of water resources, water shortage and water pollution in arid regions have become major constraints to local sustainable development. In this study, we established a Soil and Water Assessment Tool (SWAT) model for simulating non-point source (NPS) pollution in the irrigation area of the lower reaches of the Kaidu River Basin, based on spatial and attribute data (2010–2014). Four climate change scenarios (2040–2044) and two agricultural management scenarios were input into the SWAT model to quantify the effects of climate change and agricultural management on solvents and solutes of pollutants in the study area. The simulation results show that compared to the reference period (2010–2014), with a decline in streamflow from the Kaidu River, the average annual irrigation water consumption is expected to decrease by 3.84x10⁸ m³ or 8.87% during the period of 2040–2044. Meanwhile, the average annual total nitrogen (TN) and total phosphorus (TP) in agricultural drainage canals will also increase by 10.50% and 30.06%, respectively. Through the implementation of agricultural management measures, the TN and TP in farmland drainage can be reduced by 14.49% and 16.03%, respectively, reaching 661.56 t and 12.99 t, accordingly, and the increasing water efficiency can save irrigation water consumption by 4.41 x10⁸ m³ or 4.77%. The results indicate that although the water environment in the irrigation area in the lower reaches of the Kaidu River Basin is deteriorating, the situation can be improved by implementing appropriate agricultural production methods. The quantitative analysis results of NPS pollutants in the irrigation area under different scenarios provide a scientific basis for water environmental management in the Kaidu River Basin.

     

Impact of climate change on the surface water of Kaidu River Basin

To reveal the changing trend and annual distribution of the surface water hydrology and the local climate in the Bayanbuluk alpine-cold wetlands in the past 50 years, we used temperature, precipitation, different rank precipitation days, evaporation, water vapor pressure, relative humidity, dust storm days and snow depth to analyze their temporal variations. We conclude that there were no distinct changes in annual mean temperature, and no obvious changes in the maximum or minimum temperatures. Precipitation in warm season was the main water source in the wetlands of the study area and accounted for 92.0% of the annual total. Precipitation dropped to the lowest in the mid-1980s in the past 50 years and then increased gradually. The runoff of the Kaidu River has increased since 1987 which has a good linear response to the annual precipitation and mean temperature in Bayanbuluk alpine-cold wetland. Climate change also affected ecosystems in this area due to its direct relations to the surface water environment.     

新疆克里雅河源流区径流变化与气候因子关系的非线性分析

利用克里雅河源流区兰干站1957～2009年的年径流量、气温和降水量实测数据,借助小波分析和R/S分析等方法探讨了径流量、气温和降水量的变化趋势及多时间尺度相关性。结果表明:(1)年径流量与气温和降水量存在明显的正相关关系并皆呈增加趋势,结合R/S分析,这种增加趋势在未来的50a仍将可能持续。(2)研究区年径流量、气温和降水量均存在9年的年际变化周期,而在年代际上由于气温和降水量周期性不同致使径流量的周期为15年。另外,三者在未来的20年存在不同的周期性突变。(3)克里雅河源流区径流量与气温和降水量存在显著的非线性相关关系。年径流量的变化是气温和降水量综合作用的结果。     

Sensitivity of mountain runoff to climate change for Urumqi and Kaidu rivers originating from the Tianshan Mountains

The mountain watersheds of Kaidu River and Urumqi River, which separately originate from the south and north-side of the Tianshan Mountains in Xinjiang, are selected as the study area. The characteristics and trends on variation of temperature, precipitation and runoff, and the correlativity between temperature, precipitation, and runoff were analyzed based on the past 40 years of observational data from the correlative hydrological and weather stations in the study areas. Various weather scene combinations are assumed and the response models of runoff to climate change are established in order to evaluate the sensitivity of runoff to climate change in the study areas based on the foregoing analysis. Results show that all variations of temperature, precipitation, and runoff overall present an oscillating and increasing trend since the 1960s and this increase are quite evident after 1990. There is a markedly positive correlation between mountain runoff, temperature, and precipitation while there are obvious regional differences of responding degree to precipitation and temperature between mountain runoff of Urumqi River and Kaidu River Basins. Also, mountain runoff of Urumqi River Basin is more sensitive to precipitation change than that of Kaidu River Basin, and mountain runoff of Kaidu River Basin is more sensitive to temperature change than that of Urumqi River Basin.     

挠力河流域河流径流量对气候变化的敏感性分析

流域径流量对气候变化的敏感性分析是理解气候变化对流域水资源影响的重要手段。本文利用非更新式人工神经网络(ANN)模型,以年平均降雨、年最低气温和最高气温为输入参数,年平均径流量为输出变量,构建了三江平原挠力河流域的径流量预测ANN模型;并根据IPCC第四次报告的气候变化模式,设定了9种不同的气候变化情景,利用构建的ANN模型分析了流域径流量对气候变化的敏感性。结果表明:构建的人工神经网络模型能够较好的模拟径流量,可用于气候变化的敏感性分析;挠力河流域上游径流量对气候变化的敏感性要大于中游区域的,降水变化对径流量的影响大于气温对其产生的影响。     

淮河流域水文随机方法的径流图化(英文)

Theoretical difficulties for mapping and for estimating river regime characteristics in a large-scale basin remain because of the nature of the variable under study: river flows are related to a specific area, i.e. the drainage basin, and are hierarchically organized in space through the river network with upstream-downstream dependencies. Another limitation is there are not enough gauge stations in developing countries. This presentation aims at de-veloping the hydro-stochastic approach for producing choropleth maps of average annual runoff and computing mean discharge along the main river network for a large-scale basin. The approach applied to mean annual runoff is based on geostatistical interpolation proce-dures coupled with water balance and data uncertainty analyses. It is proved by an applica-tion in the upstream at Bengbu in the Huaihe River Basin, a typical large-scale basin in China. Hydro-stochasitic approach in a first step interpolates to a regular grid net and in a second step the grid values are integrated along rivers. The interpolation scheme includes a con-straint to be able to account for the lateral water balance along the rivers. Grid runoff map with 10 km × 10 km resolution and the discharge map along the river with the 1 km basic length unit are the main results in this study. This kind of statistic approach can be widely used be-cause it avoids the complexity of hydrological models and does not depend on the meteoro-logical data.     

天山东段冰雪消融与产汇流水文过程——以乌鲁木齐河源区为例

应用天山北坡乌鲁木齐河源区1 号冰川、空冰斗和总控3 个水文断面2011 年5-9 月每10min 实测水位数据、15 min 的气温、降水数据、1 号冰川消融及空冰斗区积雪观测数据,采用排除和不排除降水对冰雪消融产流影响的研究方法,系统分析了不同冰川覆盖率下水文断面冰雪消融特征及产汇流过程。结果表明：（1） 乌鲁木齐河源区3 个水文断面流量昼夜差异明显,1 号冰川水文断面白天径流大于夜晚径流,空冰斗和总控断面则相反;3 个断面流量亦具有显著日变化过程,且流量峰值大小和到来的时间存在差异。（2） 在排除与不排除降水两种天气影响下,1 号冰川最大流量滞后最高气温分别为1~3 h 和0~1 h;空冰斗断面分别为10~16 h和13 h,总控断面分别为5~11 h 和6~7 h,反映了1 号冰川从消融产流到汇流时间最短,空冰斗积雪消融产流时间最长,总控位于二者之间,同时亦反映伴随降水过程冰雪融水汇流迅速,即从产流到汇流时间有一定的缩短。（3） 影响3 个水文断面流量变化的因素不同,冰川区热量条件是影响1 号冰川水文断面的关键,1 号冰川在过去20 余年间,冰内、冰下排水道变得更为单一,对融水的阻滞和贮存作用弱化,融水汇流过程变得更为迅速。（4） 冰川覆盖山区流域水文断面在冰川消融期的流量过程线变化及最大流量与最高气温时滞变化规律在一定程度上对于认识冰川覆盖率有差异背景下的流域下垫面水系演化、冰雪消融过程及水文断面径流补给具有重要的指示意义。     

雅鲁藏布江流域径流特性变化分析

本文采用Morlet小波对1956~2000年雅鲁藏布江流域6个站点的径流序列进行了分析,揭示了不同时间尺度下四个季节以及年平均径流量的丰枯交替特性、突变性和周期性,通过小波方差确定各序列存在的主要周期。结果表明:在15年时间尺度上,雅江流域四个季节的径流变化趋势基本一致;发生突变的年份主要在1957、1967、1976、1983、1992年;径流序列第一主周期主要以15年长周期和2年短周期为主,第二主周期以15、6、2~3年的长、中、短周期为主;秋季和冬季径流序列的周期空间分布基本一致,年平均径流序列的周期分布与夏季最为接近;除拉萨河子流域春季在2~3年尺度上处于枯水期外,其他子流域其他时段在任何时间尺度上未来几年里都将处于丰水期。     

1766 年以来黄河中游与永定河汛期径流量的变化

利用清代志桩涨水尺寸和雨分寸记录、近现代器测水文与降雨数据等多种资料,重建/修正了永定河卢沟桥断面和黄河三门峡断面1766-2004 年的汛期径流量(m³/s),其在夏秋汛期的多年平均径流量分别为109.0 m³/s 和5121.1 m³/s。并依据多年径流量平均值±1 个标准差值得出了新的丰-枯水发生年表。小波分析显示两者具有较为明显的30~40 年周期,1920 年之后,永定河持续性的枯流使河流水量变化周期消失,黄河中游的高频周期则更加发育。两者在1780-1900 年存在20 年尺度上的变化同步性现象,而1840-1860 年代和1890-1910 年代两者出现了明显的反相位现象。从1766 年以来的情况分析,中国东部季风区进入20 世纪暖期之后,黄河中游与永定河卢沟桥以上流域的汛期降雨基本为反相关关系。     

阿克苏河径流变化与北大西洋涛动的关系

The relationship between North Atlantic Oscillations (NAO) and Aksu River Runoff (ARR) was investigated by using the wavelet transform (WT), cross wavelet transform (CWT), correlation and linear trend analyses, and abrupt change test. The main results are as follows: the interannual/decadal variation and period analyses of ARR and NAO reveal that the both were close correlated each other; the CWT indicates that the correlation was good between ARR and NAO at all periods in the 1990s, because the significant correlation areas mainly concentrated in the 1990s; the variations in the trend strength of ARR and NAO were consistent; the abrupt change of NAO was also temporally consistent with that of ARR, which exerted impact on the Aksu River Basin (ARB) climate and then the ARR through atmospheric circulation variation. Foundation: Special Fund for Social Public Good Project of the Ministry of Science and Technology, No.2004DIB3J118; No.2005DIB6J113; GYHY (QX) 2007-6-8; Desert Meteorological Fund, No.2007011 Author: Li Hongjun (1971–), Associate Professor, Ph.D Candidate, specialized in climate change.     

Association of North Atlantic Oscillations with Aksu River runoff in China

The relationship between North Atlantic Oscillations (NAO) and Aksu River Runoff (ARR) was investigated by using the wavelet transform (WT), cross wavelet transform (CWT), correlation and linear trend analyses, and abrupt change test. The main results are as follows: the interannual/decadal variation and period analyses of ARR and NAO reveal that the both were close correlated each other; the CWT indicates that the correlation was good between ARR and NAO at all periods in the 1990s, because the significant correlation areas mainly concentrated in the 1990s; the variations in the trend strength of ARR and NAO were consistent; the abrupt change of NAO was also temporally consistent with that of ARR, which exerted impact on the Aksu River Basin (ARB) climate and then the ARR through atmospheric circulation variation.     

Responses to climate warming of hydrological processes in the upper Kelan River in the Altay Mountains, Xinjiang, China

Kelan River is a branch of the Ertix River, originating in the Altay Mountains in Xinjiang, northwestern China. The upper streams of the Kelan River are located on the southern slope of the Altay Mountains; they arise from small glacial lakes at an elevation of more than 2,500 m. The total water-collection area of the studied basin, from 988 to 3,480 m, is about 1,655 km2. Almost 95 percent of the basin area is covered with snow in winter. The westerly air masses deplete nearly all the moisture that comes in the form of snow during the winter months in the upper and middle reaches of the basin. That annual flow from the basin is about 382 mm, about 45 percent of which is contributed by snowmelt. The mean annual precipitation in the basin is about 620 mm, which is primarily concentrated in the upper and middle basin. The Kelan River system could be vulnerable to climate change because of substantial contribution from snowmelt runoff. The hydrological system could be altered significantly because of a warming of the climate. The impact of climate change on the hydrological cycle and events would pose an additional threat to the Altay region. The Kelan River, a typical snow-dominated watershed, has more area at higher elevations and accumulates snow during the winter. The peak flow occurs as a result of snow-melting during the late spring or early summer. Stream flow varies strongly throughout the year because of seasonal cycles of precipitation, snowpack, temperature, and groundwater. Changes in the temperature and precipitation affect the timing and volume of stream-flow. The stream-flow consists of contributions from meltwater of snow and ice and from runoff of rainfall. Therefore, it has low flow in winter, high flow during the spring and early summer as the snowpack melts, and less flows during the late summer. Because of the warming of the current climate change, hydrology processes of the Kelan River have undergone marked changes, as evidenced by the shift of the maximum flood peak discharge from May to June     

The influence of climate change and human activities on runoff in the middle reaches of the Huaihe River Basin,China

This study presents a soil and water integrated model (SWIM) and associated statistical analyses for the Huaihe River Basin (HRB) based on daily meteorological, river runoff, and water resource data encompassing the period between 1959 and 2015. The aim of this research is to quantitatively analyze the rate of contribution of upstream runoff to that of the midstream as well as the influence of climate change and human activities in this section of the river. Our goal is to explain why extreme precipitation is concentrated in the upper reaches of the HRB while floods tend to occur frequently in the middle reaches of this river basin. Results show that the rate of contribution of precipitation to runoff in the upper reaches of the HRB is significantly higher than temperature. Data show that the maximum contribution rate of upstream runoff to that of the midstream can be as high as 2.23%, while the contribution of temperature is just 0.38%. In contrast, the rate of contribution of human activities to runoff is 87.20% in the middle reaches of the HRB, while that due to climate change is 12.80%. Frequent flood disasters therefore occur in the middle reaches of the HRB because of the combined effects of extreme precipitation in the upper reaches and human activities in the middle sections.     

祖厉河流域降雨径流泥沙变化特征研究

祖厉河流域位于年降水量200～400 mm之间过渡带,是气候变化最敏感和最为复杂的区域之一。运用祖厉河流域1955-2013年径流量、输沙量与年降雨量的变化趋势、时段特征进行了分析。结果表明：祖厉河流域降雨量、径流量和输沙量存在年际变化大、逐年减小的变化趋势;年降雨量在1995年出现突变点,降雨量存在明显的丰水和枯水变化,丰水时段（1955-1989年）年降水量为376.2 mm,枯水时段（1990-2013年）年降水量为224.9 mm;径流量和泥沙量的突变点分别出现在1995年和2000年;依据UF_k值信度变化趋势,将径流量、输沙量变化分为非显著减少（1955-1971年）、显著减少（1972-1985年）、较显著减少（1986-2000年）和极显著减少（2001-2013年）四个时期。     

气候变化对河北省海河流域径流量的影响

利用河北省境内海河流域51个气象站、68个水文站1956~2000年近50年的气象、径流量数据,分析了气象要素和径流量的变化规律。河北省境内海河流域多年平均地表径流量为67.0×10⁸m³,从20世纪 50 年代至 90 年代地表径流量呈逐渐减小的趋势,50年代为105.3×10⁸m³,90年代为54.7×10⁸m³。地表径流量随降水量的减少而减小,随气温的升高而下降,用回归方法建立的径流量与气象要素之间的模型为对数模型。根据未来气候变化情景对河北省海河流域径流量的预测:2030年为70.0~76.8×10⁸m³,2050年为69.8~76.9×10⁸m³。