不同土壤抗蚀性能研究

该对四川省农业科学院资阳水土保持试验所布设的７种土壤试验小区，用模拟降雨装置进行了土壤抗蚀性能的初步试验研究，结果表明：（１）７种土壤的抗蚀能力大小依次为：冷沙黄泥＞棕紫泥＞红棕紫泥＞灰色潮土＞红紫泥＞黄红紫泥＞暗棕紫泥；（２）７种土壤的么径流过程累积量与降雨历时、产沙过程累积量与降雨历时，径流过程累积量与产沙过程累积量之间均有显的线性相关关系，以及６种土壤的土壤含水量与开始产流时间之间有非常     

地表糙度与径流水力学参数响应规律模拟

为了明确地表糙度与坡面径流特征及其水力学参数之间的相互作用,通过模拟人工锄耕、人工掏挖、等高耕作和对照组直型坡等4种不同糙度的地表,在室内模拟降雨条件下,对不同糙度坡面上的径流特征和水力学参数(雷诺数、弗劳德数、阻力系数和水流剪切力)以及降雨前后地表糙度的变化进行了测量与计算。结果表明,雨前雨后各措施坡面的地表糙度为:等高耕作人工掏挖人工锄耕直型坡。相同雨强和降雨历时下,不同糙度坡面其径流特征差异显著。初始地表糙度越大的坡面,径流越容易稳定在层流状态;反之,径流越倾向于往紊流发展。对人工锄耕、人工掏挖、等高耕作3种耕作措施来说,在相同雨强和降雨历时下,初始糙度越大的坡面,其断面流量、径流量和产沙量越小。坡面初始地表糙度越大,径流阻力系数也越大,但坡面径流的雷诺数、弗劳德数和径流剪切力则越小,径流对地表糙度具有减小作用,雷诺数和水流剪切力越大,径流对地表糙度的减小作用越弱。研究结果为深入理解坡面地表糙度与其水文特征之间的相互作用提供参考。     

秸秆覆盖和有机质输入对紫色土土壤可蚀性的影响

以紫色土坡耕地为研究对象开展野外径流小区定位监测试验,设置有机质(OM)、秸秆覆盖(SW)、有机质+秸秆覆盖(OM+SW)和对照(无秸秆覆盖,不增施有机质,CK)4个处理,对2014年侵蚀性降雨条件下不同处理小区径流及产沙特征进行分析,以单位径流冲刷侵蚀量(K_w)作为土壤可蚀性指标,研究四川省中江县紫色土区秸秆覆盖和有机质输入对坡耕地土壤可蚀性的影响。结果表明:秸秆和有机质输入能显著降低紫色土区坡耕地产流量,4个处理减小径流的效果表现为OM+SWSWOMCK;有机质、秸秆覆盖均显著降低单位径流侵蚀量,从而减小土壤可蚀性,OM、SW、OM+SW处理对土壤可蚀性的平均消减率分别为22.30%、29.76%、35.04%,秸秆覆盖处理(SW)对土壤可蚀性的减小效应略高于有机质处理(OM),但二者差异不显著。综合分析得出,增施有机质的同时进行秸秆覆盖可作为紫色土区坡耕地减小土壤可蚀性的有效措施。     

Erodibility of agricultural soils on the Loess Plateau of China

Soil erodibility is thought of as the ease with which soil is detached by splash during rainfall or by surface flow. Soil erodibility is an important factor in determining the rate of soil loss. In the universal soil loss equation (USLE) and the revised universal soil loss equation (RUSLE), soil erodibility is represented by an erodibility factor (K). The K factor was defined as the mean rate of soil loss per unit rainfall erosivity index from unit runoff plots. Although high rate of soil loss from the Loess Plateau in China is well known and widely documented, it is remarkable that there is little systematic attempt to develop and validate an erodibility index for soils on the Loess Plateu for erosion prediction. Field experimental data from four sites on the Loess Plateau were analyzed to determine the K factor for USLE/RUSLE and to compare with another erodibility index based on soil loss and runoff commonly used for the region. The data set consists of event erosivity index, runoff, and soil loss for 17 runoff plots with slope ranging from 8.7 to 60.1%. Results indicate that the K factor for USLE/RULSE is more appropriate for agricultural soils on the Loess Plateau than the erodibility index developed locally. Values of the K factor for loessial soils range from 0.0096 to 0.0269 t h/(MJ mm). The spatial distribution of the K value in the study area follows a simple pattern showing high values in areas with low clay content. For the four sites investigated, the K factor was significantly related to the clay content, (K=0.031−0.0013 Cl, r²=0.75), where Cl is the clay content in percent. The measured values of the K factor are systematically lower than the nomograph-based estimates by a factor of 3.3–8.4. This implies that use of the nomograph method to estimate soil erodibility would considerably over-predict the rate of soil loss, and local relationship between soil property and the K factor is required for soil erosion prediction for the region.     

Influence of exchangeable potassium on soil erodibility

Abstract. Regular application of slurry manure in large quantities is thought to degrade soil structure and increase erodibility. One hypothesis links this to the large input of potassium which increases the exchangeable potassium percentage (EPP) and, thereby, dispersion. The effect of EPP on erodibility was quantified in three experiments. In the laboratory, eleven rainfall experiments were conducted using a silty topsoil from a typic Hapludalf which was fertilized to EPPs of 4 to 18%. Field rainfall experiments on 22 Inceptisols and Alfisols were used to examine whether the long-term application of monovalent cations (Na⁺, K⁺ and NH₄⁺) with slurry manure had changed soil properties, especially erodibility. In addition, erodibilities of 32 soils determined with natural and simulated rains were taken from literature. The experiments on these 65 soils together covered a wide range of soils, slopes and rainfalls. Dispersion by a large percentage of highly hydrated ions (K⁺, Na⁺) reduced the infiltration rate faster, caused runoff up to 5 min earlier, and increased sediment concentrations by 15g/l compared to low EPP soils. These changes increased soil erodibility of the Universal Soil Loss Equation (USLE) by 0.021 t × h/N × ha (where N = Newtons) for each 1% increase in EPP + ESP (exchangeable sodium percentage). The ESP contributed little to this increase as ESP was less than 1/10 of EPP in the experiments.
Fields with long-term manure application had similar chemical, physical and microbiological soil properties as fields without slurry manure except for slightly greater pH (+ 0.6) and P (+ 17 mg/kg) values. We conclude that, as long as the potassium input and output are balanced, the long-term use of slurry manure does not increase erodibility.     

Erodibility of a soil drainage sequence in the loess uplands of Mississippi

The susceptibility of loess soils in the lower Mississippi to runoff and erosion losses varies as a function of landscape position and mapping units. This study was conducted to determine the effects of soil drainage on physical and chemical properties that influence erodibility through their control of aggregate stability. Soil samples were collected from the A- and B-horizons of the five representative pedons in the Memphis catena whose drainage class varied from well-drained to poorly-drained. The fine earth fraction (< 2 mm) of each soil was characterized for a range of basic soil physical and chemical properties. Additional sub-samples (< 8 mm) were placed in a rainfall simulator pan (0.6 m × 0.6 m test area) and subjected to simulated rainfall at an intensity of 64 mm h^− 1. Soil erodibility was assessed by the use of an aggregation index (AI) computed from water dispersible clay (WDC) relative to total clay contents. The data show that as soil drainage classes became wetter, the percentage of sediment < 53 µm increased with a decrease in soil AI resulting from a loss of Fe, Al, and Si oxide cementing agents. These results suggest that cementing agents responsible for soil aggregate stabilization are mobilized under conditions of relatively low redox potentials which increase soil erodibility.     

土壤可蚀性研究进展综述

土壤可蚀性是表征土壤对降雨渗透能力及其对降雨和径流剥蚀、搬运敏感程度的一个综合指标,是反映土壤侵蚀的重要参数。介绍了国内外学者提出的土壤可蚀性指标,评述了直接测定法、公式法和诺谟图法的优缺点与应用范围;结合我国土壤可蚀性研究现状,介绍了我国土壤侵蚀严重区的典型土壤可蚀性指标值的最新研究成果,分析了我国土壤可蚀性研究的不足,指出应加强并完善土壤可蚀性指标、土壤可蚀性影响因子和土壤可蚀性计算方法的研究。     

聚丙烯酰胺对扰动红壤可蚀性及临界剪切力的影响

为了利用化学措施防治工程水土流失,研究了聚丙烯酰胺（PAM）对扰动红壤土壤可蚀性及临界剪切力的影响。采用室内人工模拟降雨试验,探讨了5o、10o、15o、20o、25o 5种坡度,0.8、1.1、1.4 mm/min 3种雨强下不同土壤处理后坡面水动力学参数、径流输沙率与流量、土壤可蚀性及临界剪切力的变化关系。试验结果表明,在相同的径流流量下,对照的输沙率是施加PAM后的300倍;施加PAM后,红壤扰动土的可蚀性由13.223 g/(min·N)降低到0.2693 g/(min·N),径流的临界剪切力大小由0.77 N/(m2·min)增加到1.47 N/(m2·min)。施加PAM可显著降低土壤可蚀性,增加径流临界剪切力。研究成果为PAM应用于工程水土流失防治提供了一定的理论依据。     

红壤团聚体特征与坡面侵蚀定量关系

为明确红壤结构特征对坡面侵蚀过程的影响,选取6种典型红壤为研究对象,通过团聚体稳定性分析和野外原位人工模拟降雨试验,就红壤团聚体稳定性特征与坡面侵蚀过程定量关系进行了初步探讨。结果表明：在野外尺度上,红壤团聚体稳定性是影响坡面侵蚀的重要因素;能定量描述土壤可蚀性的团聚体特征参数Ka,与径流强度、产沙强度等侵蚀参数显著相关;将Ka代入WEPP模型,建立了细沟间侵蚀预测方程,方程可决系数较高（R2＝0.86）,显示了较好的预测性能。该研究扩展了团聚体稳定性作为土壤可蚀性指标的适用范围,为红壤侵蚀机理研究提供了新思路。     

Vergleich deutscher und schweizer Regensimulatoren - Einfluß der Regeneigenschaften auf die Bodenoberflächenrauhigkeit

Comparison of German and Swiss Rainfall Simulators - Influence of Rainfall Characteristics on Soil Surface Roughness Six different field rainfall simulators were compared. Soil surface roughness was tested by a simple field method before and after rainfall simulation. Preparation of the test site with a rotary cultivator inadvertently entailed spatial variability of roughness and aggregate size. Thus, the plots with finer seedbed showed higher runoff and soil loss. The relative decrease of roughness could best be correlated with the total kinetic energy as well as with the R factor of the different simulators (r = 0.87 resp. 0.91). Thus, the degree of soil surface leveling was shown to be due to the rainfall characteristics of the different simulator types. However, there was no relation between change of soil surface roughness and runoff. The relative classification of the kinetic energy of the rainfall simulators explained the leveling of the soil surface better than the classifications previously used in many studies (r = 0.91 as against r = 0.73).     

Influence of simulated rainfall on physical properties of a conventionally tilled loess soil

Rainfall simulations were conducted on a loess derived silt loam soil (Henan province, P.R. China) under conventional tillage. This tillage practice is widespread and involves the turning of the plough layer and the wheat stubble in July (primary tillage), followed by a secondary tillage operation in October. Soil samples were collected and in situ measurements were done before each rainfall simulation in order to analyse soil physical properties after successive simulated rainfall events. The purpose of this study was to determine rainfall induced changes in saturated hydraulic conductivity, bulk density, penetration resistance, water retention and soil erodibility. The results only showed significant differences in soil bulk density and erodibility when applying successive rainfall events. Penetration resistance and water retention (at matric potentials ≤ − 3 kPa) were not significantly affected and soil surface sealing was not observed. This was also confirmed by the infiltration measurements, where no significant differences in saturated hydraulic conductivity were found. From a soil conservation point of view, this study indicated that the primary tillage operation (i.e. ploughing at the beginning of July) is rather disadvantageous: the saturated hydraulic conductivity is not significantly affected, but the soil erodibility is considerably higher in comparison to a consolidated soil. Furthermore, the beneficial effects of the wheat stubble on soil and water conservation are lost by the tillage operation.     

降雨和上方来水条件下工程堆积体坡面土壤侵蚀特征

定量分析降雨和上方来水共同作用下堆积体坡面产流产沙过程,对于完善多驱动力条件下堆积体坡面土壤侵蚀特征具有重要意义。该研究运用人工模拟降雨和冲刷试验,在野外径流小区(7 m×1 m×0.5 m,坡度36°)上分别开展5个降雨强度(40、50、70、100、120 mm/h)、4个上方来水强度(10、15、20、25 L/min)单独作用及共同作用下坡面土壤侵蚀过程试验,比较2种驱动力单独作用及共同下堆积体坡面土壤侵蚀与形态特征。结果表明:1)降雨条件下,堆积体坡面侵蚀过程呈现阶段性差异发育,中小雨强(40、50和70mm/h)条件下,产流率和产沙率随历时延续呈现2个不同阶段(波动、平稳),侵蚀形态为不连续跌坎,大雨强(100和120 mm/h)条件下,产流率和产沙率随历时的延续呈现3个不同阶段(波动、平稳、剧烈),坡面侵蚀形态为细沟。2)上方来水条件下,堆积体坡面侵蚀过程呈现相对平稳发育,坡面侵蚀形态均为细沟。3)上方来水与降雨共同作用下,堆积体坡面侵蚀过程呈现剧烈波动发育,产沙率随历时的延续呈现持续"多峰多谷"变化态势,随着时间延续,产沙率波动振幅逐渐增大,堆积体坡面侵蚀形态均为侵蚀沟,且发育剧烈。4)上方来水和降雨共同作用下,坡面径流量和泥沙量均增大,且泥沙量的增大幅度大于径流量,相比单独降雨,径流量和泥沙量分别增大86%~629%和86%~4914%,相比单独上方来水,径流量和泥沙量分别增大12%~175%和15%~505%。上方来水和降雨共同作用下,汇流与降雨之间存在交互作用,两者对径流和泥沙的影响均显著。研究结果对于完善堆积坡面土壤侵蚀特征及揭示复杂水动力条件下的侵蚀机理具有重要意义。     

冻融条件下土壤可蚀性对坡面氮磷流失的影响

冻融作用与水力侵蚀的复合作用更容易使土壤发生侵蚀,进而加剧土壤养分的流失,为了揭示冻融作用下土壤可蚀性对坡面养分流失的影响,该文采用室内模拟降雨试验,研究了不同土壤含水率(SWC)下坡面的降雨产流产沙及养分流失特征,并分析了土壤可蚀性对坡面全氮(TN)和全磷(TP)流失的影响。结果表明:产流率与产沙率之间呈现正线性相关关系,相关方程斜率的绝对值可作为土壤可蚀性指标。径流中氮磷的流失主要受径流率控制,受土壤可蚀性影响较小(P0.05);而土壤可蚀性显著影响着泥沙中氮磷和总的氮磷流失(P0.01)。土壤可蚀性对黄土坡面氮素流失的影响与冻融作用有关,而土壤可蚀性对坡面磷素流失的影响与冻融作用无关,磷素的流失随着土壤可蚀性增加而增加。因此,在黄土地区,应当采取一系列的生态建设措施来控制水土流失,降低土壤可蚀性,从而减少坡面养分的流失。该研究结果为冻融条件下黄土坡面水-土和氮磷等养分流失机制提供了有效指导。     

翻耕与压实对坡地土壤溶质迁移过程的影响

采用田间模拟降雨试验方法,研究地表翻耕与压实处理对坡地产流产沙及溶质迁移特征的影响。结果表明：与压实处理比较,翻耕坡地初始产流时间延长近3倍,降雨向土壤水转化率提高10％以上,产沙量增加67％;翻耕处理明显降低溶解态磷（DP）和泥沙浸提态磷（SEP）的流失量,但磷素流失形态（DP与SEP的比值）并未显著变化,始终以颗粒态形式流失为主;翻耕处理显著改变了溴的流失形态,溶解态溴（Br）与泥沙浸提态溴（SBr）流失量比值减少了72％;翻耕处理提高了溴（或硝态氮）的淋失概率,增大污染地下水体的潜在危险。因此,合理配置坡地免耕或翻耕措施,有机结合其他农艺耕作措施,对减少坡地水土及养分流失具有重要实践意义。     

Effects of rainfall intensity and slope gradient on the dynamics of interrill erosion during soil surface sealing

Soil erosion during rainfall is strongly affected by runoff and slope steepness. Runoff production is drastically increased when a seal is formed at the soil surface during rainfall. Therefore, a complex interaction exists between soil erosion and surface sealing. In this study, the dynamics of interrill erosion during seal formation is studied under different simulated rainfall and slope conditions. A sandy soil was exposed to 70 mm of rainfall at two intensities, 24 mm h^− 1 and 60 mm h^− 1, and five slope gradients, from 5% to 25%. Infiltration, runoff and soil loss rates were monitored during rainfall. Final infiltration rates increased with slope gradient at both rainfall intensities, this effect being stronger for the higher intensity. Cumulative runoff at the end of the rainfall event was lower as slopes were steeper, while an opposite trend was obtained for soil loss. For the 5% and the 9% slopes, the sediment concentration in runoff reached quickly a stable value during the whole rainfall event, while it reached a peak value before declining for the higher slopes. The peak value and its timing were rainfall intensity dependent. Soil erodibility during seal formation was evaluated using two empirical multiplication-of-factors type models. It seems that slope and rainfall erosivity are accounted for only partly in these models. For mild slope gradients below 9%, the value of K_i estimated by means of the two expressions becomes practically constant shortly after runoff apparition. Consequently, the estimates resulting from this type of expressions remain valuable from the practical point of view.     

Effects of soil crust and crop on runoff and erosion in Loess Plateau

Soil crust formed after rainfall has a strong influence on soil erosion, water use, and crop growth on sloping farmland. To study the effect of soil crust on sloping farmland on runoff amount and erosion sediment yield, the soil crust on sloping farmland has been studied in this paper for plantings of corn, soybeans, millet, and winter wheat. Using an outdoor rainfall simulator, the influence of soil crust on runoff rate and sediment yield on sloping farmland covered by crops has been observed. The results revealed that soil crust thickness was increased after rainfall and soil crust coverage showed little change after rainfall. Soil crust had a significant impact on runoff and sediment yield on sloping farmland. Slopes with soil crust showed higher runoff rate and less soil loss than slopes without soil crust. On slopes planted with four crops (corn, soybeans, millet, and winter wheat), runoff rates on slopes with soil crust were respectively 20%, 25%, 25%, and 21% higher than on slopes without soil crust; sediment yield on slopes with soil crust was respectively 15%, 14%, 14%, and 8% lower than on slopes without soil crust. Crops enlarged the runoff difference between the two kinds of slope and decreased the sediment yield difference between them. Crop growth enhanced these differences in runoff and sediment yield between slopes with and without soil crust.     

Assessing Soil Properties Controlling Interrill Erosion: An Empirical Approach under Mediterranean Conditions

Soil erodibility is a complex phenomenon that comprises a number of different soil properties. However, most current (empirical) erodibility indices are based on only a few soil properties. A feasible soil characterization of interrill erosion (IE) prediction at large scale should be based on simple, quick and inexpensive tests to perform. The objective of this work was to identify and assess those soil properties that best reflect soil vulnerability to IE. Twenty‐three agricultural soil samples located in Spain and Italy were studied. Forty‐nine different physical and chemical soil properties that presumably underpin IE were defined. Experiments were carried out in the field (in microplots using simulated rainfall) and in the lab. The most relevant variables were detected using multivariate analysis. Six key variables were finally identified: RUSLE K factor, a granulometric/organic matter content index, exchangeable sodium percentage, shear strength, penetration resistance and permeability of soil seal. The latter is proposed as a useful technique to evaluate soil susceptibility to crusting even when the crust is not present at the time of the field survey. The selected variables represented a wide range of soil properties, and they could also be successfully applied to different soils with different characteristics than those evaluated in our experiments. Copyright © 2017 John Wiley & Sons, Ltd.     

降雨-径流条件下土壤溶质迁移过程模拟

通过雨滴的打击加速土壤表面溶质迁移至地表径流过程。通过设计3种水文条件即控制排水状态（-5 cm）、土壤水分饱和状态和土壤渗流状态（5 cm）,采用人工模拟3种降雨强度（30、60和90 mm/h）,及同时外加模拟相对于降雨量的0、2、4和10倍径流量,研究土壤溶质迁移到地表径流过程中扩散过程的规律。试验结果表明降雨强度、或地表径流总量、或地表水位线的增加,均加速土壤溶质的扩散过程。渗流作用下,对流-扩散作用存在着一种交互作用,能加速分子扩散过程。土壤溶质迁移过程同降雨强度、地表径流量和地下水位高低有着重要关系。     

河北省表层土壤可侵蚀性K值评估与分析

利用河北土系调查成果中的土壤颗粒组成、土地利用及土壤化学性质等资料,利用EPIC模型中土壤可蚀性K值算法以及结合地统计学方法,研究了不同土壤类型、不同质地及不同土地利用类型的土壤可侵蚀性K值和土壤可侵蚀性K值的空间变异特征。结果表明:1河北土壤可侵蚀性K值平均为0.27,其变化范围为0.12~0.40,土壤可蚀性K值在0.30~0.35之间易蚀性土壤面积占总土地面积的63.71%,土壤可蚀性K值在0.25~0.3之间较易蚀性土壤面积占总土地面积的21.52%,这说明该省易蚀性土壤面积较大。2不同质地的K值之间显著性差异,粉砂黏壤质的可侵蚀性K值最大,为0.37;壤砂质的可侵蚀性K值最小,为0.13。而在不同的土地利用类型之间的K值差异性不显著,耕地的K值最大,为0.33;草地的K值最小,为0.22。3河北土壤可侵蚀性K值存在较强的变异性,其变异系数为29%。因此,在土壤侵蚀定量监测、评价水土流失时,应考虑土壤可蚀性K值的这种空间变异状况。块金值/基台值为37.3%,表明在变程内具有中等强度的空间相关性。步长为23 km,变程为440 km,变程远大于步长,表明在小流域尺度下有较好的空间相关性,进行Kriging插值能得到较准确的结果。4河北土壤可蚀性K值大体呈现南高北低的空间分布特征,南部主要是耕作栽培区,北部主要是自然植被区。该研究结果为宏观大尺度土壤资源可持续利用与制定水土保持规划提供科学依据。