黄土坡耕地地表微地形空间变异性研究

以黄土高原普遍采用的人工锄耕、人工掏挖和等高耕作等管理措施的坡耕地为研究对象,利用半方差方法分析了不同耕作措施下坡面相对高程空间变异结构特征,以期为开展数值模拟坡面微地形的研究提供理论支持.结果表明:不同耕作措施下坡面相对高程具有较强的空间相关性,依次为等高耕作＜人工掏挖＜人工锄耕;人工锄耕与人工掏挖坡面具有自相似性特...     

覆沙坡面微地形变化与侵蚀产沙的响应关系

坡面微地形的发育反映了侵蚀的强度及变化过程。为了定量研究不同覆沙厚度下坡面的微地形变化与侵蚀之间的响应,通过模拟1. 5 mm·min~(-1)雨强下的3场连续降雨试验,结合三维激光扫描仪技术,分析了坡面微地形与土壤侵蚀的空间变化特征,较好地拟合了微地形变幅与侵蚀量之间的关系。结果表明:坡面平均含沙量随着降雨场次的增加而减小。覆沙坡面主要产沙区的长度是黄土坡面的3倍左右,且坡段侵蚀量的峰值多分布在坡面4～6 m的位置,而黄土坡面侵蚀峰值分布在3～4 m的位置。随着降雨场次的增加,黄土坡面微地形因子显著增大(P 0. 05),覆沙坡面微地形因子总体呈增大趋势,但并不显著(P 0. 05)。与黄土坡面和覆沙坡面的侵蚀响应最强烈的微地形因子分别为地表切割深度和地表粗糙度,黄土坡面微地形变幅与侵蚀量的响应关系较强于覆沙坡面,覆沙坡面应寻找其他敏感的指标对方程进行优化。该研究为揭示风水复合侵蚀地区的侵蚀机理提供一定参考。     

基于WEPP模型进行坡度因子与侵蚀量关系研究

地面坡度是地形因素中对坡面土壤侵蚀的演变发展过程与侵蚀强度起重要作用的因子。本文以内蒙古准格尔旗皇甫川坡面径流小区的实测资料为基础,分析坡度因子与土壤侵蚀量的关系,并运用WEPP模型进行模拟,对其结果进行分析。结果表明在一定的坡度范围内,随着坡度的增加,土壤侵蚀量与坡度呈幂函数递增关系。用WEPP模型来模拟皇甫川流域坡面与侵蚀量的关系是可行的,根据试验观测及WEPP模型模拟得到结果,皇甫川地区的土壤侵蚀率在坡度是18~23o时最大,原因主要有坡度的陡缓决定了水力阻力的大小和坡面承雨面积的改变等。     

黄土丘陵沟壑区陡坡微地形分布研究

水分是黄土丘陵沟壑区植被建设的主要限制因素,而陡坡的水分条件差,导致坡面上水分空间差异的微地形成为陡坡坡面植被恢复的关键因素。利用三维激光扫描全站仪实测陕西省吴起县合家沟流域的地形参数,以Arc GIS 9.2为平台,对切沟、浅沟、缓台、塌陷和陡坎5种微地形在陡坡坡面的分布情况进行了研究。结果表明：陡坡坡面微地形占坡面面积比例介于18%～30%,平均为23.13%;各类微地形占坡面面积比例平均值从大到小依次为切沟8.44%、缓台6.66%、浅沟5.00%、陡坎1.53%、塌陷1.52%;坡面坡向和坡面坡度是影响浅沟、切沟和塌陷占坡面面积比例的主要地形要素,陡坎占坡面面积比例主要受坡面坡度的影响,而坡面坡向与坡面坡度对缓台占坡面面积比例均没有明显的影响;不同坡向陡坡微地形占坡面面积比例大小顺序为：阳坡＞半阳坡＞半阴坡＞阴坡,塌陷、浅沟和切沟占坡面面积比例为阳坡和半阳坡大于半阴坡和阴坡;陡坎、浅沟和切沟占坡面面积比例随着坡度的增大而减小、塌陷占坡面面积比例随着坡度的增大而增大。     

降雨强度对农业耕作措施水土保持作用的影响

利用人工模拟降雨试验，研究不同降雨强度下，不同农业耕作措施坡地水土流失特征。试验设计的坡地坡度分别为5°和15°，降雨强度分别为60、90、120 mm·h^-1；耕作措施分别为等高耕作、人工掏挖和人工锄耕，以相同坡度的平整坡地作为对照。结果表明：（1）随着降雨强度的增大，各耕作措施坡地产流量显著增大1.51倍以上，最大增加幅度为等高耕作坡地的2.28倍。而坡地产沙量在降雨强度较小时增加不显著，当降雨强度增大到120 mm·h^-1时，坡地产沙量显著增大；（2）与平整坡地相比，等高耕作在3个降雨强度下都具有明显的减流效益，减流量均大于15%，而人工锄耕和人工掏挖却不明显；（3）在5°坡地上，等高耕作和人工掏挖在3个降雨强度的减沙效益均大于25%，而人工锄耕减沙效益不明显；在坡度为15°、降雨强度为60 mm·h^-1和90 mm·h^-1时，人工锄耕和人工掏挖减沙效益与降雨强度关系无明显规律，在降雨强度为120 mm·h^-1时，3个耕作措施都不能有效降低坡地产沙量。可见，水土保持农业耕作措施具有降低坡地产流量的作用，而对于坡地产沙的作用存在明显差异，在大坡度和大降雨强度下，不仅不能降低坡地产沙，反而加剧坡地土壤流失。     

晋西黄土区不同地类降雨-坡面径流关系研究

利用径流小区研究黄土区坡面降雨—径流关系,对探讨该区水土流失规律、构建基于坡面的水文模型具有重要意义。文中利用布设在山西吉县森林生态系统国家野外科学观测研究站的径流小区,对不同地类的产流特征进行了观测研究。研究得出:在坡面尺度上不同地类的径流系数、洪峰流量差异显著;各地类对地表径流的拦截率分别为:由山杨、辽东栎等树种组成的次生林96%、刺槐人工林95%、灌木林88%、荒草地61%、油松人工林41%;各地类对洪峰流量的消减率分别为:次生林94%、刺槐林92%、灌木林82%、荒草地66%、油松林49%;在同一地类上径流系数与雨强的关系具有季节变化性;径流系数与雨强呈指数关系;在雨强相同条件下,春秋季节的降雨比夏季更易形成地表径流;洪峰流量与I30或I10的呈指数关系,但I30与洪峰流量的关系优于I10。     

京津水源区坡耕地土壤侵蚀特征分析

坡耕地是保障粮食安全与经济发展的重要资源.本文利用承德市南山径流场资料对不同坡长下径流深、含沙量及侵蚀量进行对比分析,结果显示:坡长和降雨强度都对土壤侵蚀有影响,随着坡长变化,导致土壤侵蚀量变化的两个主导因素不断变换.雨强小于0.25 mm/min时,坡面土壤侵蚀模数随坡长的增加而增大;雨强大于0.25mm/min时,随坡长的增加先增大后减小,最大侵蚀量总是出现在22 m坡长范围内.径流深均值与侵蚀量增量随坡长变化趋势一致,含沙量均值变化与雨强关系密切.所以治理京津水源区坡耕地水土流失,应在22 m坡长以内采取等高植物篱等措施,既可降低工程投入,又减少坡面土壤流失,提高土地生产力.     

黄土坡面土壤侵蚀过程试验研究

采用人工模拟降雨的方法对黄土坡面土壤侵蚀过程进行了试验研究,取得了如下结果:①坡面土壤侵蚀随降雨过程的变化可用幂函数相关方程进行描述,15 m in和35 m in是土壤侵蚀强度随降雨过程变化的转折点;②雨强对坡面土壤侵蚀的影响可用幂函数相关方程进行描述,随着坡度的增大,土壤侵蚀强度随雨强的增大而增加的趋势更明显;③坡度对土壤侵蚀的影响可用抛物线相关方程进行描述,土壤侵蚀强度变化的临界坡度在25°附近;④坡长对土壤侵蚀的影响大体可用幂函数相关方程进行描述,但坡长对土壤侵蚀强度的影响比较复杂,随雨强大小的变化而表现为不同的形式;⑤坡度、坡长及雨强对坡面土壤侵蚀的综合影响可用多元线性相关方程进行描述,雨强对土壤侵蚀强度的影响远大于坡长及坡度因子,且坡度与土壤侵蚀强度的关系较坡长为密切。     

侵蚀作用对黄土丘陵沟壑区有机碳迁移-沉积的影响

土壤有机碳(SOC)作为陆地碳库的重要组成部分,不仅对土壤肥力产生重要影响,而且在一定程度上影响着全球变暖趋势,为了深入探究土壤侵蚀与有机碳的关系,利用137 Cs核示踪法,以黄土丘陵沟壑区典型流域王茂沟坡耕地、林地、草地和梯田四种土地利用为研究对象,分析了不同坡面下土壤侵蚀对SOC迁移和沉积的影响规律。结果表明:与该流域137 Cs面积浓度背景值相比(1237 Bq/m²),坡耕地平均137 Cs面积浓度最小,平均137 Cs流失率最大,达到95.86%。根据侵蚀速率,四种坡面景观侵蚀速率大小依次为:坡耕地>草地>林地>梯田。根据土壤有机碳空间分布特征发现,除坡耕地外,林地、草地和梯田土壤沉积与土壤侵蚀同时发生,并且土壤137 Cs面积浓度与有机碳面积浓度呈现显著相关关系(p<0.05)。研究结果表明采用137 Cs核示踪法可以较为科学的解释该区域土壤侵蚀作用对坡面有机碳迁移-沉积的影响规律。     

薄土坡耕地石坎反坡水平阶水沙调控效果

为研究石坎反坡水平阶对于薄土坡耕地的水沙调控效果,设置了两个标准天然降雨径流小区（措施小区和对照小区）分别对次降雨径流和泥沙进行了观测,结果表明：石坎反坡水平阶措施能够有效地调控坡耕地地表径流,年均径流削减率为22.5%,且在短历时、大雨强降雨条件下的调控效果好于长历时、小雨强降雨;该措施对于坡耕地泥沙调控效果显著且稳定,年均泥沙削减率95.5%,措施小区的坡面产沙量随降雨特征值变化的波动幅度远远小于对照小区;石坎反坡水平阶措施通过减少坡面侵蚀,间接提高了坡耕地作物产量,春玉米年均增产6.2%。     

Effects of structural and depositional crusts on soil erosion on the Loess Plateau of China

Conventional tillage practices used on the Loess Plateau lead to different soil surface micro-topography which results in forming two types of soil crusts. The objective of this study was to explore the formation position, properties and erosion characteristics of structural crusts and depositional crusts under the influences of the microtopography in the rainfall experiments. Two simulated rainstorms were applied in the experiments. The first rainfall event was used for soil crust formation, then the following simulated rainfall storms at 40 mm h^?1, 60 mm h^?1, and 80 mm h^?1 rates were applied to the soil boxes set to a 17.6% (10°) slope under three tillage types (contour tillage, artificial digging, and straight slope conditions) to investigate the resulting runoff discharge rate and sediment yield on crusted soil surface. Results show that: (1) structural crusts formed on the mounds, and depositional crusts formed in the depressions after the first rainfall events; structural crusts exhibit a lower thickness, bulk density, higher porosity and shear strength than depositional crusts; (2) structural crusts increased the runoff yield less and decreased the sediment yield more than depositional crusts; and (3) the runoff yield was significantly greater, and the sediment yield was lower on the crusted soil surface than that on the uncrusted soil surface, regardless of the effect of the tillage treatments.     

黄土区土质道路径流水动力学参数的灰色关联度分析

黄土区土质道路路面侵蚀是该地区土壤侵蚀中的重要形式之一,为了探讨其土壤剥蚀率与径流水动力学参数的相关关系,以便为该地区道路土壤侵蚀预报模型的建立提供帮助,采用室内人工降雨及放水冲刷实验、灰色关联度分析方法研究了裸露土质路和植草土质路的径流水动力学参数与土壤剥蚀率间的关系,结果表明:1)在15°坡度、不同雨强条件下,可根据径流量或水流功率计算土壤剥蚀率;2)在2mm.min-1雨强、不同坡度条件下,可根据水流功率或坡度计算土壤剥蚀率;3)在降雨加放水冲刷试验条件下,裸露土质路的土壤剥蚀率可通过径流水深或径流流速计算得出,而植草土质路的土壤剥蚀率可通过过水断面单位能量或径流量计算得出。因此,在无汇水条件时,根据径流水流功率计算土壤剥蚀率较为合理;在有汇水条件时,采用径流量计算土壤剥蚀率较为合理。     

Two-dimensional hydrodynamic robust numerical model of soil erosion based on slopes and river basins

Erosion is an important issue in soil science and is related to many environmental problems, such as soil erosion and sediment transport. Establishing a simulation model suitable for soil erosion prediction is of great significance not only to accurately predict the process of soil separation by runoff, but also improve the physical model of soil erosion. In this study, we develop a graphic processing unit (GPU)-based numerical model that combines two-dimensional (2D) hydrodynamic and Green-Ampt (G-A) infiltration modelling to simulate soil erosion. A Godunov-type scheme on a uniform and structured square grid is then generated to solve the relevant shallow water equations (SWEs). The highlight of this study is the use of GPU-based acceleration technology to enable numerical models to simulate slope and watershed erosion in an efficient and high-resolution manner. The results show that the hydrodynamic model performs well in simulating soil erosion process. Soil erosion is studied by conducting calculation verification at the slope and basin scales. The first case involves simulating soil erosion process of a slope surface under indoor artificial rainfall conditions from 0 to 1000 s, and there is a good agreement between the simulated values and the measured values for the runoff velocity. The second case is a river basin experiment (Coquet River Basin) that involves watershed erosion. Simulations of the erosion depth change and erosion cumulative amount of the basin during a period of 1-40 h show an elevation difference of erosion at 0.5-3.0 m, especially during the period of 20-30 h. Nine cross sections in the basin are selected for simulation and the results reveal that the depth of erosion change value ranges from -0.86 to -2.79 m and the depth of deposition change value varies from 0.38 to 1.02 m. The findings indicate that the developed GPU-based hydrogeomorphological model can reproduce soil erosion processes. These results are valuable for rainfall runoff and soil erosion predictions on rilled hillslopes and river basins.     

Freeze-thaw effects on erosion process in loess slope under simulated rainfall

Seasonal freeze-thaw processes have led to severe soil erosion in the middle and high latitudes. The area affected by freeze-thaw erosion in China exceeds 13% of the national territory. So understanding the effect of freeze-thaw on erosion process is of great significance for soil and water conservation as well as for ecological engineering. In this study, we designed simulated rainfall experiments to investigate soil erosion processes under two soil conditions, unfrozen slope (UFS) and frozen slope (FS), and three rainfall intensities of 0.6, 0.9 and 1.2 mm/min. The results showed that the initial runoff time of FS occurred much earlier than that of the UFS. Under the same rainfall intensity, the runoff of FS is 1.17-1.26 times that of UFS; and the sediment yield of FS is 6.48-10.49 times that of UFS. With increasing rainfall time, rills were produced on the slope. After the appearance of the rills, the sediment yield on the FS accounts for 74%-86% of the total sediment yield. Rill erosion was the main reason for the increase in soil erosion rate on FS, and the reduction in water percolation resulting from frozen layers was one of the important factors leading to the advancement of rills on slope. A linear relationship existed between the cumulative runoff and the sediment yield of UFS and FS (R²>0.97, P<0.01). The average mean weight diameter (MWD) on the slope erosion particles was as follows: UFS0.9 (73.84 μm)>FS0.6 (72.30 μm)>UFS1.2 (72.23 μm)>substrate (71.23 μm)>FS1.2 (71.06 μm)>FS0.9 (70.72 μm). During the early stage of the rainfall, the MWD of the FS was relatively large. However, during the middle to late rainfall, the particle composition gradually approached that of the soil substrate. Under different rainfall intensities, the mean soil erodibility (MK) of the FS was 7.22 times that of the UFS. The ratio of the mean regression coefficient C₂ (MC₂) between FS and UFS was roughly correspondent with MK. Therefore, the parameter C₂ can be used to evaluate soil erodibility after the appearance of the rills. This article explored the influence mechanism of freeze-thaw effects on loess soil erosion and provided a theoretical basis for further studies on soil erosion in the loess hilly regions.     

An experimental study on the influences of wind erosion on water erosion

In semi-arid regions, complex erosion resulted from a combination of wind and water actions has led to a massive soil loss and a comprehensive understanding of its mechanism is the first step toward prevention of the erosion. However, the mutual influences between wind erosion and water erosion have not been fully understood. This research used a wind tunnel and two rainfall simulators and simulated two rounds of alternations between wind erosion and water erosion(i.e., 1~(st) wind erosion–1~(st) water erosion and 2~(nd) wind erosion–2~(nd) water erosion) on three slopes(5°, 10°, and 15°) with six wind speeds(0, 9, 11, 13, 15, and 20 m/s) and five rainfall intensities(0, 30, 45, 60, and 75 mm/h). The objective was to analyze the influences of wind erosion on succeeding water erosion. Results showed that the effects of wind erosion on water erosion were not the same in the two rounds of tests. In the 1~(st) round of tests, wind erosion first restrained and then intensified water erosion mostly because the blocking effect of wind-sculpted micro-topography on surface flow was weakened with the increase in slope. In the 2~(nd) round of tests, wind erosion intensified water erosion on beds with no rills at gentle slopes and low rainfall intensities or with large-size rills at steep slopes and high rainfall intensities. Wind erosion restrained water erosion on beds with small rills at moderate slopes and moderate rainfall intensities. The effects were mainly related to the fine grain layer, rills and slope of the original bed in the 2~(nd) round of tests. The findings can deepen our understanding of complex erosion resulted from a combination of wind and water actions and provide scientific references to regional soil and water conservation.     

坡度对黄土坡面径流溶质迁移特征的影响

通过田间模拟降雨试验,分析了坡度对坡面物质迁移特性的影响.结果显示,坡度对坡面物质迁移的影响十分显著;降雨强度一定时,坡度达到15°左右时,径流量达到最大;坡度对径流养分流失量的影响是通过径流量起主导作用,径流量大相应径流携带养分流失总量增加.利用幂函数对径流溶质浓度变化过程进行了拟合,结果显示幂函数可以很好反映田间坡面溶质随地表径流变化过程,说明在侵蚀环境下径流溶质浓度变化过程符合幂函数.     

Influences of sand cover on erosion processes of loess slopes based on rainfall simulation experiments

Aeolian-fluvial interplay erosion regions are subject to intense soil erosion and are of particular concern in loess areas of northwestern China.Understanding the composition,distribution,and transport processes of eroded sediments in these regions is of considerable scientific significance for controlling soil erosion.In this study,based on laboratory rainfall simulation experiments,we analyzed rainfall-induced erosion processes on sand-covered loess slopes(SS)with different sand cover patterns(including length and thickness)and uncovered loess slopes(LS)to investigate the influences of sand cover on erosion processes of loess slopes in case regions of aeolian-fluvial erosion.The grain-size curves of eroded sediments were fitted using the Weibull function.Compositions of eroded sediments under different sand cover patterns and rainfall intensities were analyzed to explore sediment transport modes of SS.The influences of sand cover amount and pattern on erosion processes of loess slopes were also discussed.The results show that sand cover on loess slopes influences the proportion of loess erosion and that the compositions of eroded sediments vary between SS and LS.Sand cover on loess slopes transforms silt erosion into sand erosion by reducing splash erosion and changing the rainfall-induced erosion processes.The percentage of eroded sand from SS in the early stage of runoff and sediment generation is always higher than that in the late stage.Sand cover on loess slopes aggravates loess erosion,not only by adding sand as additional eroded sediments but also by increasing the amount of eroded loess,compared with the loess slopes without sand cover.The influence of sand cover pattern on runoff yield and the amount of eroded sediments is larger than that of sand cover amount.Furthermore,given the same sand cover pattern,a thicker sand cover could increase sand erosion while a thinner sand cover could aggravate loess erosion.This difference explains the existence of intense erosion on slopes that are thinly covered with sand in regions where aeolian erosion and fluvial erosion interact.     

黄土耕作坡面微地形面积高程积分计算及特征研究

面积高程积分(Hypsometric Integral,HI)是定量表征地形发育阶段及侵蚀趋势的重要指标。通过90mm/h雨强下4个典型坡度的人工模拟分段降雨试验,在三维激光扫描的基础上,利用点云数据生成DEM,对微地形坡面HI值的3种计算方法及其变化特征进行了分析,并根据细沟河网格网的HI值进行了验证。结果表明:1)HI方法可用于微地形坡面侵蚀发育的定量表征,HI值介于0.50-0.59之间。在不同坡度条件下,细沟出现之前坡面侵蚀量逐渐增加且HI总体呈现递减趋势,而细沟出现后侵蚀量在细沟中有所堆积且HI值有一定回增。2)河网格网HI值介于0.45±0.11之间。随着坡度的增加,HI值总体上表现出增加的趋势,潜在侵蚀能力有增大的趋势且侵蚀量和坡度之间存在一定的转折关系。3)对比3种不同HI计算精度来看,坡面HI与格网HI之间的RMSE和SAE值差别并不明显,但总体均表现为积分曲线法的计算精度要略优于体积比例法和起伏比法。研究结果对于丰富微地形尺度下HI的计算,深入认识坡面侵蚀发育过程及其机理具有重要的参考价值。