1960-2009年中国降雨侵蚀力的时空变化趋势

降雨侵蚀力反映了降雨对土壤侵蚀的潜在能力,因此降雨侵蚀力已经成为土壤侵蚀、产沙和水环境建模的主要参数之一。利用中国590个气象站1960-2009年逐日降雨量资料估算了中国每个气象站的降雨侵蚀力,并使用趋势系数、气候倾向率和Kriging空间插值方法分析了中国降雨侵蚀力的时空变化趋势。结果表明:我国年均降雨侵蚀力从东南沿海向西北内陆逐渐递减,与年均降水量空间分布基本一致;近50年来我国大部分地区年降雨侵蚀力呈现不显著的上升趋势,存在四个明显的上升区域和两个明显的下降区域;59个气象站年降雨侵蚀力变化趋势通过了0.05显著水平的置信度检验,年降雨侵蚀力显著增加的气象站主要分布在青藏高原中东部、东缘、天山山脉以及东南沿海区域。青海省的诺木洪-都兰-曲麻莱-伍道梁一带近50年来年降雨侵蚀力增加趋势最为显著,有可能加剧长江、黄河源头土壤侵蚀的风险。     

ENSO对韶关市1951~2013年降雨侵蚀力影响研究

选取1951~2013年韶关市分月降雨量数据,采用月降雨侵蚀力模型计算降雨侵蚀力,分析ENSO（厄尔尼诺-南方涛动）对韶关市降雨侵蚀力的影响。研究表明：① 韶关市降雨侵蚀力年际变化和年内变化较大,总体呈现波动上升趋势;② 降雨侵蚀力与赤道太平洋SST距平值呈现极显著相关,降雨侵蚀力随SST距平值增加呈现先增加后递减的趋势。ENSO冷暖事件发生时降雨侵蚀力较小,在其它土壤侵蚀因素不变的条件下,此时期的土壤侵蚀相对较轻;③ 降雨侵蚀力与SOI存在显著相关,降雨侵蚀力随着SOI增加而减小;④ 降雨侵蚀力与MEI呈现极显著的正相关关系。     

粤北岩溶区连江流域降雨侵蚀力

对连江流域35个气象站1980―2013年逐日雨量数据进行整理,利用日雨量、月雨量和年雨量方法计算得出RA、RB、RC,通过有效系数M检验得出最优R值;然后利用反距离加权、张力样条函数和普通克里金进行空间插值,通过检验确定最准确的插值方法,最后对其进行插值分析。结果表明：基于月降雨量的计算方法和反距离加权插值法更加适合于连江流域降雨侵蚀力的计算和估算;连江流域降雨侵蚀力时空变化明显,降雨侵蚀力变化与年际降水量变化基本一致;中上游高大山脉存在的地区,多年平均降雨侵蚀力明显高于其他地区;下游多年平均降雨量丰富,其多年平均降雨侵蚀也较严重。     

文山州降雨侵蚀力时空分布规律浅析

降雨是导致土壤侵蚀的主要动力因素,降雨侵蚀力反映降雨引起土壤侵蚀的潜在能力。利用文山州内21个雨量代表站月降雨资料,估算文山州降雨侵蚀力,对该地区降雨侵蚀力的年内分布、年际变化特征和空间分布变化规律进行分析。结果表明：文山州降雨侵蚀力空间分布基本与降雨一致,山区为高值区,坝区为低值区;降雨侵蚀力主要集中在汛期（5～10月）,各月的差异大于降雨量的差异;文山州降雨侵蚀力长期变化为略减小趋势但不显著,年际变化较年降雨量年际变化显著。     

1961—2015年雅鲁藏布江流域降雨侵蚀力

降雨是土壤侵蚀的主要动力,也是风水蚀复合区沙漠化的主要驱动力。研究降雨侵蚀力时空变化对雅鲁藏布江流域土壤侵蚀的监测、评估、预报和治理具有重要意义。利用1961—2015年雅鲁藏布江流域8个气象站日降雨量气象资料,采用趋势系数、气候倾向率、MK检验等研究方法对雅鲁藏布江流域降雨侵蚀力时空变化进行分析。结果表明:雅鲁藏布江流域年降雨侵蚀力平均值为758.1 MJ·mm·hm^-2·h^-1,变差系数Cv值为0.29,趋势系数r值为0.3140。空间分布呈现由东向西逐渐递减的特点,东部可达2 000 MJ·mm·hm^-2·h^-1以上,最西部仅为200MJ·mm·hm^-2·h^-1。雅鲁藏布江流域年降雨侵蚀力总体呈波动上升趋势,其中嘉黎和波密站年降雨侵蚀力上升趋势明显,日喀则、泽当站年降雨侵蚀力呈下降趋势。通过MK检验及滑动T检验得知,流域内年降雨侵蚀力在1982年发生突变,年侵蚀性降雨突变不显著。雅鲁藏布江流域年降雨侵蚀力与侵蚀性降雨相关性显著。     

黄河中游降雨特性对泥沙粒径的影响

以黄河中游36个有泥沙粒径资料的水文测站流域为样本，在不同自然地理类型流域划分的基础上，建立了流域泥沙粒径特片与降雨特性的关系。结果表明，在不同类型流域，流域泥沙的粗细与降雨季节性变率和年际变率之间存在着相当好的线性正相关关系；而与年降雨量和降雨不均匀系数之间呈明显的非线性关系。流域地面物质、植被和地貌发育程序等下垫面环境因素对泥沙粒径特性与降雨特性之间关系起着十分重要的控制作用。不同类型流域曲线的斜率各不相同，在图中所处的位置也不相同。     

基于CLDAS融合降水的中国降雨侵蚀力研究

气象站和卫星降雨资料估算降雨侵蚀力时存在无法反映空间异质性且精度差的问题,基于CLDAS多源融合降水,利用EI₆₀模型从不同的时空尺度对中国的降雨侵蚀力进行评估,并结合降雨量、侵蚀性降雨次数、侵蚀密度等指标,探讨降雨对土壤侵蚀的潜在作用。结果表明：（1） CLDAS降雨侵蚀力与地面实测数据在不同的时间尺度均有良好的回归关系,相关系数达到0.8以上,与CMORPH降雨侵蚀力相比,其相对误差显著降低,可以准确反映全国范围的降雨侵蚀力季节性变异。（2） 在2001—2020年,不同雨量区的降雨侵蚀力、降雨量和侵蚀性降雨次数的变化趋势基本一致,高雨量区的年际变化波动剧烈,侵蚀性降雨次数和暴雨过程协同影响降雨侵蚀力的大小。（3） 空间上,中国的降雨侵蚀力值的特点为东南沿海地区高、西北内陆地区低。时间上,侵蚀性降雨集中在5—8月,夏、秋两季对土壤造成的侵蚀影响更大。（4） 通过对年降雨量、年侵蚀密度和年暴雨量进行分区定量分析,结果表明暴雨量与侵蚀密度成正相关关系,即年降雨量一定,暴雨事件越多,降雨侵蚀密度越大。     

黄土高原塬面保护区降雨侵蚀力时空分布特征及其影响因素研究

通过采用Mann-Kendall趋势分析法、小波分析方法、地统计插值等方法,基于黄土高原塬面保护区及临近的21个站点的逐日降水量数据,对区域内降雨侵蚀力的时空变化,趋势及主要影响因素进行了分析。结果表明：(1) 黄土塬面保护区1960—2017年多年平均降雨量为599.2 mm;多年平均降雨侵蚀力为1 871.91 MJ·mm·hm^-2·h^-1·a^-1,降雨侵蚀力在过去60 a来呈微弱上升趋势且变化的季节差异显著。(2) 黄土高原塬面保护区降雨侵蚀力的空间分布大体呈由南部向两侧递减的趋势,Mann-Kendall Z值除研究区北部、东部呈下降趋势,其余区域都为上升趋势。(3) 黄土高原塬面保护区降雨侵蚀力多年存在32 a的大周期,在大周期内还存在13 a、52 a的小周期。(4) 影响北半球中高纬度地区的主要的大气环流因子中仅Cold & Warm Episodes by Season因子的波动对整个区域和陕西塬区的降雨侵蚀力有一定影响,二者存在一定的负相关性,其余环流指数与降雨侵蚀力没有显著的关联性;此外太阳黑子与陕西塬区降水侵蚀力变化规律存在一定的正相关,与其他塬区并无显著关联性。     

Application of USLE in a GIS environment to estimate soil erosion in the Irga watershed,Jharkhand, India

A comprehensive methodology that integrates the Universal Soil Loss Equation (USLE) and Geographic Information System (GIS) was adopted in this study to determine the soil erosion and sediment yield of the Irga watershed in Jharkhand, India. Based on the availability and applicability of data in a GIS-environment, the original equations for the model input parameters were, however, modified by researchers. In the present study, a power-law equation was generated to estimate the rainfall erosivity (R) factor, and the Nash-Sutcliffe model efficiency coefficient used to determine the accuracy of the modified R factor. Average annual soil erosion in the Irga watershed is estimated to be 4.3 t ha^?1 yr^?1. On the other hand, average annual sediment yield of the watershed, estimated using the sediment delivery ratio, was found to be 1.2 t ha^?1 yr^?1. Low sediment yield indicates that most of the eroded soil was deposited within the watershed.     

广东省主要站点降雨侵蚀力时间分布规律研究

利用广东省6个站点47 a的日雨量资料,计算并分析了各站降雨侵蚀力的时间分布规律。结果表明,根据降雨侵蚀力峰值在年内出现的次数,可以分为单峰型和双峰型。降雨侵蚀力的年内分布非常集中,连续3个月的降雨侵蚀力平均占全年侵蚀力的一半以上,越靠近沿海的站点侵蚀力的集中度越高。降雨量与降雨侵蚀力集中度的分布规律一致,但与降雨量相比,降雨侵蚀力的分布更加集中。各站降雨量与降雨侵蚀力的倾向率均大于零,说明自1954年以来,雨量和降雨侵蚀力均有不同程度的增加趋势,降雨侵蚀力的增幅远远大于降雨量的增幅。但降雨侵蚀力倾向率的年内分布却是正负皆有。     

砒砂岩地区降雨与植被耦合关系对侵蚀产沙的影响

研究降雨--植被耦合关系对侵蚀产沙的影响,为侵蚀治理提供数据支持.基于TRMM降雨数据和MODIS 250 m NDVI,分析降雨和植被的年内分布模式和匹配关系,并构建降雨--植被耦合指数RV,用于反映侵蚀产沙状况.进一步利用年降雨量,NDVI以及其分布参数(峰度系数和偏斜度)与输沙量进行相关分析和多元回归分析.结果显示:降雨的集中,偏斜程度和波动性要比植被更为明显;RV与实际输沙量的相关系数为0.84,可以很好地反映侵蚀产沙的相对大小;年输沙量与降雨的分布参数相关性最高,达到0.94和0.87,对提高回归模型的拟合程度影响也最大;考虑降雨量,NDVI及其分布参数的模型的拟合程度最好,R_a²达到0.9232.因此,降雨与植被的年内匹配模式对侵蚀产沙具有重要影响.     

黄河中游小流域坡沟侵蚀关系研究

根据坡面水下沟时在沟坡（道）上“净产沙增量”的概念,探讨了沿程含沙水流侵蚀特性的变化和坡沟侵蚀关系及产沙机理,并采用成因分析法定量确定了典型小流域的泥沙来源。     

Quantifying fluvial non linearity and finding self organized criticality? Insights from simulations of river basin evolution

A numerical study was undertaken to investigate non linearity and the potential for self-organized criticality (SOC) in the evolution of river basins. Twenty-three simulations were carried out, using the authors' CAESAR landscape evolution model, in which the magnitude of storm events, variability of storm events, sediment heterogeneity, sources of sediment supply, and catchment morphology are systematically varied to evaluate their importance as possible drivers for non linear behavior and SOC.Temporal fluctuations in simulated sediment yield show notable non linear behavior. Storm magnitude and occurrence of landslides appear to have little impact on variability of the sediment yield, when compared to the impacts of sediment heterogeneity, rainfall variability and catchment morphology. Particularly, it appears that the non linearity of sediment yields results from the manner in which the catchment processes the variable rainfall, rather than just the rainfall variability itself.The variations in sediment yield show a power law magnitude–frequency distribution, which is a possible, but inconclusive, indicator of SOC. However, several other, more qualitative arguments can be made to support the case for SOC in these simulations. Specifically, we identify the nature of the critical state and suggest two cascade mechanisms by which the system can organize itself around this critical state. Combined, these arguments indicate that simulated evolution of river basins indeed exhibits SOC, at least with respect to sediment yield. The critical state appears to be an indicator of the connectivity of the drainage network. Thus, the simulations indicate that, unlike traditional SOC systems, the critical state of the system can vary in time, as sudden changes in drainage network connectivity may result in sudden changes in the SOC behavior of the system.     

TRMM数据在中国降雨侵蚀力计算中的应用

长时间序列降雨过程资料的获取一直是降雨侵蚀力计算中的一个难题。尝试利用地面实测站点数据分别对TRMM(Tropical Rainfall Measuring Mission)卫星的3B43和3B42数据进行回归建模和订正,并采用订正后的3 h平均降雨强度代替30 min最大降雨强度,同时基于TRMM数据的EI180的降雨侵蚀力算法,计算出了全国南北纬50°范围(TRMM覆盖区)内2013年月、季和年降雨侵蚀力;最后分别计算了省域和区域尺度下的降雨侵蚀力对全国尺度下的结果进行对比验证。结果表明:(1) TRMM降水数据比地面站点观测的降水量略大,但与实测站点数据具有很好的线性回归关系,其季尺度决定系数R²均较高,由此也说明了TRMM数据可以很好地反映全国范围内降雨的季节性变化。(2)利用订正后的TRMM3B42数据计算出研究区内的年均降雨侵蚀力为536.02 MJ·mm·hm^-2·h^-1·a^-1,其降雨侵蚀主要集中在5~8月份。(3) 2013年全国降雨侵蚀变化趋势由东南向西北方向逐渐降低,且沿海省份较内陆省份降雨侵蚀较高。(4)通过对年降雨侵蚀力结果与实测站点降雨量以及订正的TRMM降水数据分析表明,降雨侵蚀力与降水之间存在着紧密的二次非线性关系。(5)通过尺度验证,其中省域尺度验证误差为8.34%,区域尺度误差仅为0.24%,由此说明了TRMM数据在不同尺度下均具有良好的适应性,同时也验证了方法在不同尺度下的有效性。该方法为有效解决土壤侵蚀中降雨强度计算资料缺乏的瓶颈,同时也为降雨侵蚀力的计算提供了一条有效的途径。     

Effects of high-magnitude/low-frequency fluvial events generated by intense snowmelt or heavy rainfall in arctic periglacial environments in northern Swedish Lapland and northern Siberia

Abstract In the Latnjavagge drainage basin (68°21′N, 18°29′E), an arctic‐oceanic periglacial environment in northernmost Swedish Lapland, the fluvial sediment transport and the characteristics and importance of high‐magnitude/low‐frequency fluvial events generated by intense snowmelt or heavy rainfall have been investigated and compared with snowmelt‐ and rainfall‐induced discharge peaks in the Levinson‐Lessing Lake basin (Krasnaya river system) on the Taimyr Peninsula, an arctic periglacial environment in northern Siberia (74°32′N, 98°35′E). In Latnjavagge (9 km²) the intensity of fluvial sediment transport is very low. Most of the total annual sediment load is transported in a few days during snowmelt generated runoff peaks. Due to the continuous and very stable vegetation covering most areas below 1300 m a.s.l. in the Latnjavagge catchment, larger rainfall events are of limited importance for sediment transport in this environment. Compared to that, in the c. 40 times larger Krasnaya riversystem rainfall‐generated runoff peaks cause significant sediment transport. The main sediment sources in the Latnjavagge drainage basin are permanent ice patches, channel debris pavements mobilized during peak discharges and exposing fines, and material mobilized by slush‐flows. In the Krasnaya river system river bank erosion is the main sediment source. In both periglacial environments more than 90% of the annual sediment yield is transported during runoff peaks. The results from both arctic periglacial environments underline the high importance of high‐magnitude/low‐frequency fluvial events for the total fluvial sediment budgets of periglacial fluvial systems. Restricted sediment availability is in both arctic environments the major controlling factor for this behaviour.     

全球视野下崩岗侵蚀地貌及其研究进展

典型的崩岗具有“圆形露天剧场”般的沟头,发育在深厚的红色花岗岩风化壳上,通常包括集水坡面、崩壁、崩积体、沟道、洪积扇5个地貌组成部分;崩壁自上而下可分为表土层、风化红粘土层(红土层)、风化砂质红粘土层(砂土层)、风化粗碎屑层(碎屑层)。中国的崩岗与马达加斯加的lavaka属于同类地貌,两者具有地貌学上的可比性。崩岗群是劣地的表现形式之一,但与欧洲的badland有不同的侵蚀过程,也不同于意大利和巴西的两种沟谷侵蚀地貌calanchi和vocoroca。崩岗主要发育在华南和东南热带和亚热带湿润季风气候区中等偏缓的丘陵坡地上,由沟谷侵蚀发展而成,是沟谷侵蚀的高级阶段。崩岗沟道侵蚀产沙量占崩岗沟谷流域侵蚀产沙量的一半以上,其中沟道沟壁崩塌侵蚀产沙量与沟床下切侵蚀产沙量又各占崩岗沟道侵蚀产沙量的一半左右。野外人工模拟降雨试验是研究崩岗流域侵蚀、产流和产沙过程的有效手段。崩岗流域侵蚀产沙量可以通过崩岗沟谷和洪积扇地形测量加以估算。     

Suspended Sediment Yield from the Ansager Å river basin,Denmark

Geografisk Tidsskrift, Danish Journal of Geography 98: 38–45.

Water samples have been collected since 1969, at the Lavborg Bridge gauging station, on the river Ansager Å in South-West Jutland. Different regression equations of concentration versus discharge have been tested. The regression equations are used together with daily discharges to compute the daily suspended loads. Comparisons between measured and computedloads for different periods when water samples were taken twice a day suggest that the 25 computed annual load values have an uncertainty of less than ± 10%. The variation in annual loads shown is therefore significant and probably caused by increased rainfall in the eigthies. The average total suspended sediment yield for the 25 year period was 7 t/km²/year, of which the organic load contributed 3.2 t/km²/year.     

Reconstructing high-magnitude/low-frequency landslide events based on soil redistribution modelling and a Late-Holocene sediment record from New Zealand

A sediment record is used, in combination with shallow landslide soil redistribution and sediment-yield modelling, to reconstruct the incidence of high-magnitude/low-frequency landslide events in the upper part of a catchment and the history of a wetland in the lower part. Eleven sediment cores were obtained from a dune-impounded wetland at Te Henga, west Auckland, northern New Zealand. Sediment stratigraphy and chronology were interpreted by radiocarbon dating, foraminiferal analysis, and provisional tephrochronology. Gradual impoundment of the wetland began c. 6000 cal yr BP, coinciding with the start of a gentle sea-level fall, but complete damming and initial sedimentation did not begin until c. 1000 cal yr BP. After damming, four well-defined sediment pulses occurred and these are preserved in the form of distinct clay layers in most of the sediment cores. For interpreting the sediment pulses, a physically based landslide model was used to determine spatially distributed relative landslide hazard, applicable at the catchment scale. An empirical landslide-soil redistribution component was added and proved able to determine the volumes and spatial pattern of eroded and deposited soil material, sediment delivery ratio and the impact on total catchment sediment yield. Sediment volumes were calculated from the wetland cores and corresponding landslide scenarios are defined through back-analysis of modelled sediment yield output. In general, at least four major high-magnitude landslide events, both natural and intensified by forest clearance activities, occurred in the catchment upstream of Te Henga Wetland during the last c. 1000 years. The spatial distribution of modelled critical rainfall values for the catchment can be interpreted as an expression of shallow landslide hazard. The magnitude of the sediment pulses represented in the wetland can be back-calculated to critical rainfall thresholds representing a shallow landslide model scenario.     

Modelling runoff and erosion for a semi-arid catchment using a multi-scale approach based on hydrological connectivity

Runoff and erosion processes are often non-linear and scale dependent, which complicate runoff and erosion modelling at the catchment scale. One of the reasons for scale dependency is the influence of sinks, i.e. areas of infiltration and sedimentation, which lower hydrological connectivity and decrease the area-specific runoff and sediment yield. The objective of our study was to model runoff and erosion for a semi-arid catchment using a multi-scale approach based on hydrological connectivity. We simulated runoff and sediment dynamics at the catchment scale with the LAPSUS model and included plot and hillslope scale features that influenced hydrological connectivity. The semi-arid Carcavo catchment in Southeast Spain was selected as the study area, where vegetation patches and agricultural terraces are the relevant sinks at the plot and hillslope scales, respectively. We elaborated the infiltration module to integrate these runoff sinks, by adapting the parameters runoff threshold and runoff coefficient, which were derived from a rainfall simulation database. The results showed that the spatial distribution of vegetation patches and agricultural terraces largely determined hydrological connectivity at the catchment scale. Runoff and sediment yield for the scenario without agricultural terraces were, respectively, a factor four and nine higher compared to the current situation. Distributed hydrological and erosion models should therefore take account of relevant sinks at finer scales in order to correctly simulate runoff and erosion-sedimentation patterns.     

Geomorphic characterization and diversity of the fluvial systems of the Gangetic Plains

The extensive Gangetic alluvial plains are drained by rivers which differ strongly in terms of hydrological and sediment transport characteristics. These differences are manifested in the geomorphic diversity of the plains. The Western Gangetic Plains (WGP) are marked by a degradational topography with incised channels and extensive badland development in some parts, while the Eastern Gangetic Plains (EGP) are characterized by shallow, aggrading channels with frequent avulsions and extensive flooding. We interpret such geomorphic diversity in terms of differences in stream power and sediment supply from the catchment areas. The rivers draining the western plains are marked by higher stream power and lower sediment yield that result in degradation. In comparison, the rivers draining the eastern Gangetic Plains have lower stream power and higher sediment yield that result in aggradation. The variation of stream power, a function of channel slope and high sediment yield, is attributed to differences in rainfall and rate of uplift in the hinterland. It is suggested that such differences have resulted in a marked geomorphic diversity across the plains. It is also suggested that such diversity has existed for a fairly long time because of climatic and tectonic variance.