中国黄土高原丘陵沟壑区天然降雨下不同土地利用方式的水土流失效应（英文）

The Loess Plateau,which is located in the arid and semi-arid areas of China,experiences significant soil erosion due to intense human activities and soil erodibility.It is necessary to explore and identify the land-use types or land-use patterns that can control soil erosion and achieve certain agricultural production capabilities.This study established runoff plots with two slope gradients(5°and 15°) in north of Yan'an,one area of the Loess Plateau,with 3 single land-use types(cultivated land,CL;switchgrass,SG;and abandoned land,AL) and 2 composite land-use types(CL-SG and CL-AL).Prom 2006 to 2012,we continuously monitored the rainfall characteristics,runoff depth,soil loss,vegetation coverage,and soil physical properties.The results indicated a general trend in the number of runoff and soil loss events for the 5 land-use types:CL = CL-SG CL-AL SG AL.The general trend for runoff depth,soil loss,their magnitudes of variation,and the slopes of rainfall-runoff regression equation was CL CL-SG CL-AL SG AL,whereas the rainfall threshold for runoff generation exhibited the opposite trend.Results of nonparametric test regarding runoff depth/EI_(30) and soil loss/EI_(30),where EI_(30) is the product of rainfall kinetic energy and the maximum rainfall intensity over 30 min,and the runoff depth-soil loss relationship regression indicated that the effect of CL-AL was similar to that of SG;SG was similar to AL;and CL-AL,SG,and AL were superior to CL with regard to soil and water conservation.Runoff depth and soil loss significantly increased as the slope gradient increased.Runoff depth and soil loss were significantly correlated with the soil particle size composition and bulk density,respectively.The strongest significant correlations were found between runoff depth and vegetation coverage as well as between soil loss and vegetation coverage,which showed that vegetation coverage was the primary factor controlling soil erosion.Therefore,the composite land-use type CL-AL and the artificial grassland(SG) are appropriate options because both soil conservation and a certain degree of agricultural production are necessary in the study area.     

中国黄土高原丘陵沟壑区天然降雨下不同土地利用方式的水土流失效应

The Loess Plateau, which is located in the arid and semi-arid areas of China, experiences significant soil erosion due to intense human activities and soil erodibility. It is necessary to explore and identify the land-use types or land-use patterns that can control soil erosion and achieve certain agricultural production capabilities. This study established runoff plots with two slope gradients (5^O and 15^O) in north of Yan’an, one area of the Loess Plateau, with 3 single land-use types (cultivated land, CL; switchgrass, SG; and abandoned land, AL) and 2 composite land-use types (CL-SG and CL-AL). From 2006 to 2012, we continuously monitored the rainfall characteristics, runoff depth, soil loss, vegetation coverage, and soil physical properties. The results indicated a general trend in the number of runoff and soil loss events for the 5 land-use types: CL = CL-SG > CL-AL > SG> AL. The general trend for runoff depth, soil loss, their magnitudes of variation, and the slopes of rainfall-runoff regression equation was CL > CL-SG > CL-AL > SG > AL, whereas the rainfall threshold for runoff generation exhibited the opposite trend. Results of nonparametric test regarding runoff depth/EI₃₀ and soil loss/EI₃₀, where EI30 is the product of rainfall kinetic energy and the maximum rainfall intensity over 30 min, and the runoff depth-soil loss relationship regression indicated that the effect of CL-AL was similar to that of SG; SG was similar to AL; and CL-AL, SG, and AL were superior to CL with regard to soil and water conservation. Runoff depth and soil loss significantly increased as the slope gradient increased. Runoff depth and soil loss were significantly correlated with the soil particle size composition and bulk density, respectively. The strongest significant correlations were found between runoff depth and vegetation coverage as well as between soil loss and vegetation coverage, which showed that vegetation coverage was the primary factor controlling soil erosion. Therefore, the composite land-use type CL-AL and the artificial grassland (SG) are appropriate options because both soil conservation and a certain degree of agricultural production are necessary in the study area.     

坡地开垦的径流泥沙响应

Land use and land cover change is a key driver of environmental change. To investigate the runoff and erosion responses to frequent land use change on the steep lands in the Three Gorges area, China, a rainfall simulation experiment was conducted in plots randomly selected at a Sloping Land Conversion Program site with three soil surface conditions: existing vegetation cover, vegetation removal, and freshly hoed. Simulated rainfall was applied at intensities of 60 (low), 90 (medium), and 120 mm h 1 (high) in each plot. The results indicated that vegetation removal and hoeing significantly changed runoff generation. The proportion of subsurface runoff in the total runoff decreased from 30.3% to 6.2% after vegetation removal. In the hoed plots, the subsurface runoff comprised 29.1% of the total runoff under low-intensity rainfall simulation and the proportion rapidly decreased with increasing rainfall intensity. Vegetation removal and tillage also significantly increased soil erosion. The average soil erosion rates from the vegetation removal and hoed plots were 3.0 and 10.2 times larger than that in the existing vegetation cover plots, respectively. These identified that both the runoff generation mechanism and soil erosion changed as a consequence of altering land use on steep lands. Thus, conservation practices with maximum vegetation cover and minimum tillage should be used to reduce surface runoff and soil erosion on steep lands.     

大型蒸渗仪和径流小区中红壤的水量平衡

The daily soil water budgets in the red soil areas of central Jiangxi Province, southern China, were investigated with a large-scale weighing lysimeter and runoff plots. From 1998 to 2000, peanuts (Arachis hypogaea L.) and rape (Brassica napus L.) were planted in the lysimeter and in 1999, peanuts were planted in the runoff plots. The soil water budget components including rainfall, runoff, percolation and evapotranspiration were measured directly or calculated by Richards' equation and water balance equation. The results showed that most rainfall, including rainstorms, occurred from March to July, and induced the greatest soil water percolation during the year. The evapotranspiration was still large from July to September when rainfall was minimal. Thus, the lack of synchronization in soil water inputs and losses was disadvantageous to crops growing in this region. Among the soil water losses, percolation was the largest, followed by evapotranspiration, and then soil runoff. Runoff was very small on farmland with crops. It was significantly different from the uncultivated uplands where large-scale runoff was usually reported. The soil water storage fluctuated sinusoidally, with a large amplitude in the rainy season and a small amplitude in the dry season.     

Water Budget Analysis of Red Soils in Central JiangxiProvince, China

The daily soil water budgets in the red soil areas of central Jiangxi Province, southern China, were investigatedwith a large-scale weighing lysimeter and runoff plots. From 1998 to 2000, peanuts (Arachis hypogaea L.) and rape(Brassica napus L.) were planted in the lysimeter and in 1999, peanuts were planted in the runoff plots. The soil waterbudget components including rainfall, runoff, percolation and evapotranspirat.ion were measured directly or calculated by Richards‘ equation and water balance equation. The results showed that most rainfall, including rainstorms, occurredfrom March to July, and induced the greatest soil water percolation during the year. The evapotranspiration was stilllarge from July to September when rainfall was ininimal. Thus, the lack of synchronization in soil water inputs and losseswas disadvantageous to crops growing in this region. Among the soil water losses, percolation was the largest, followed byevapotranspiration, and then soil runoff. Runoff was very small on farmland with crops. It was significantly different, fromthe uncultivated uplands where large-scale runoff was usually reported. The soil water storage fluctuated sinusoidally,with a large amplitude in the rainy season and a small amplitude in the dry season.     

中国云南滇池流域农田径流磷污染负荷影响因素研究

Effects of factors such as slope, surface soil texture, fertilization and crop cover with different rainfall intensities on phosphorus (P) losses in farmland runoff of the Dianchi Lake Watershed in Yunnan Province of China were studied through a rainfall simulation test using a red soil, one of the most widely distributed soils of the study area. Results showed that the runoff concentrations of total phosphorus (TP) and P losses differed with the slope, being highest when the slope was 18°. At two different rainfall intensities, the runoff TP and P losses had a similar decreasing trend as the surface soil texture became coarser, therefore applying the grit would decrease P in runoff from soils of farmland on slopes with heavier textures. With wheat as a crop cover the runoff TP concentrations and P losses were significantly lower than those of the bare soil. This showed that plant cover would greatly decrease P in runoff from the farmland of the study area. The TP concentration in runoff from the soil two days after fertilization doubled when compared with that from the non-fertilized soil, indicating that fertilization could mean a dramatic rise in P runoff if irrigation or heavy rainfall occurred immediately after application and that no fertilization before a rain and no irrigation immediately after fertilization would reduce runoff P loss from the farmland of the study area.     

Field-scale spatial variability of soil calcium in a semi-arid region: Implications for soil erosion and site-specific management

Excess calcium(Ca) in soils of semi-arid and arid regions has negative effects on soil structure and chemical properties, which limits the crop root growth as well as the availability of soil water and nutrients. Quantifying the spatial variability of soil Ca contents may reveal factors influencing soil erosion and provide a basis for site-specific soil and crop management in semi-arid regions. This study sought to assess the spatial variability of soil Ca in relation to topography, hydraulic attributes, and soil types for precision soil and crop management in a 194-ha production field in the Southern High Plains of Texas,USA. Soils at four depth increments(0–2, 0–15, 15–30, and 30–60 cm) were sampled at 232 points in the spring of 2017. The Ca content of each sample was determined with a DP-6000 Delta Premium portable X-ray fluorescence(PXRF) spectrometer. Elevation data was obtained using a real-time kinematic GPS receiver with centimeter-level accuracy. A digital elevation model(DEM) was derived from the elevation data, and topographic and hydraulic attributes were generated from this DEM. A generalized least-squares model was then developed to assess the relationship between soil Ca contents of the four layers and the topographic and hydraulic attributes. Results showed that topographic attributes, especially slope and elevation, had a significant effect on soil Ca content at different depths(P 0.01). In addition, hydraulic attributes, especially flow length and sediment transport index(STI), had a significant effect on the spatial distribution of soil Ca. Spatial variability of soil Ca and its relationships with topographic and hydraulic attributes and soil types indicated that surface soil loss may occur due to water or wind erosion, especially on susceptible soils with high slopes. Therefore, this study suggests that the application of PXRF in assessing soil Ca content can potentially facilitate a new method for soil erosion evaluation in semi-arid lands. The results of this study provide valuable information for site-specific soil conservation and crop management.     

黄土高原土壤养分的损失

The soil nutrient losses due to excessive soil loss on Loess Plateau were studied by means of runoff plots and systematical determination of soil nutrients both in sediments and runoff.The results show that the amounts of nutrient losses depended on the amounts of ersoion sediments.Along with sediment,11-197kg nitrogen/hectare and 9-174kg phosphorus/hectare were lost,accounting for 92.46-99.47 percent of the total amount of nitrogen loss and 99.85-99.99 percent of the total amount of phosphorus loss respectively.The nutrient losses,very small in runoff,were mainly attributed to erosion of a few rainstorms during a year.The nutrient level in sediment was mostly higher than that in the original soil.Planting grass evidently redued the losses of soil nutrients.The N level was lower in runoff than in rainfall so that the N loss from runoff could be made up by rainfall.Fertilizer application to crops raised the nutrient level in runoff.     

SCS-CN模型在具有高空间异质性小流域径流预测中的应用

For reasons of simplicity, the most commonly used hydrological models are based on the Soil Conservation Service Curve Number (SCS-CN) model, which is probably a good choice for the estimation of runoff on the Loess Plateau of China; however, the high spatial heterogeneity, mainly caused by a fragmented landform and variations in soil type, may limit its applicability to this region. Therefore, applicability of the SCS-CN model to a small watershed, Liudaogou on the plateau, was evaluated and the most appropriate initial abstraction ratio (Ia/S) value in the model was quantified by the inverse method. The results showed that the standard SCS-CN model was applicable to the estimation of runoff in the Liudaogou watershed and the model performance was acceptable according to the values of relative error and Nash-Sutcliffe effciency. The most appropriate Ia/S value for the watershed was 0.22 because with this modified Ia/S value, the model performance was slightly improved. The model performance was not sensitive to the modification of the Ia/S value when one heavy rainfall event (50.1 mm) was not considered, which implied that the model, using a standard Ia/S value, can be recommended for the Liudaogou watershed because single rainfall events exceeding 50 mm seldom occurred in that region. The runoff amount predicted for the Liudaogou watershed by the SCS-CN model, using the modified Ia/S value, increased gradually with increasing rainfall when rainfall values were lower than 50 mm, whereas the predicted amount increased rapidly when the rainfall exceeded 50 mm. These findings may be helpful in solving the problem of serious soil and water loss on the Loess Plateau of China.     

Factors Influencing Runoff P Losses from Farmlandsof the Dianchi Lake Watershed in Yunnan, China

Effects of factors such as slope, surface soil texture, fertilization and crop cover with different rainfall intensitieson phosphorus (P) losses in farmland runoff of the Dianchi Lake Watershed in Yunnan Province of China were studiedthrough a rainfall simulation test using a red soil, one of the most widely distributed soils of the study area. Resultsshowed that the runoff concentrations of total phosphorus (TP) and P losses differed with the slope, being highest whenthe slope was 18~. At two different rainfall intensities, the runoff TP and P losses had a similar decreasing trend asthe surface soil texture became coarser, therefore applying the grit would decrease P in runoff from soils of farmland onslopes with heavier textures. With wheat as a crop cover the runoff TP concentrations and P losses were significantlylower than those of the bare soil. This showed that plant cover would greatly decrease P in runoff from the farmland ofthe study area. The TP concentration in runoff from the soil two days after fertilization doubled when compared withthat from the non-fertilized soil, indicating that fertilization could mean a dramatic rise in P runoff if irrigation or heavyrainfall occurred immediately after application and that no fertilization before a rain and no irrigation immediately afterfertilization would reduce runoff P loss from the farmland of the study area.     

黄土丘陵区不同坡度撂荒草地入渗特征影响因素试验研究

降雨特征和坡度是影响土壤入渗过程的重要因素,在植被恢复过程中,其对土壤入渗特征的影响可能会有所不同。选取黄土丘陵区6个坡度(5°,10°,15°,20°,25°和30°)的撂荒草地(2年)径流小区(5 m×20 m),观测自然降雨条件下(共计34场降雨,产流11场)植被生长旺期(7—9月)土壤入渗特征,研究降雨过程参数(降雨量、平均雨强、降雨历时和I_(30))、坡度和植被盖度对坡面入渗特征的影响。结果表明:(1)11场产流降雨不同坡度土壤入渗量总体变化范围为6.58～70.91 mm,入渗补给系数为0.83～1.00,入渗率为0.22～19.35 mm/h;(2)土壤入渗量随降雨量呈线性增加(R~2=0.99,p0.01),入渗补给系数随I_(30)呈指数降低(R~2=0.91,p0.01),平均入渗率随降雨强度呈线性增加(R~2=0.71,p0.01),随降雨历时呈幂函数降低(R~2=0.99,p0.05);(3)坡度增大使得径流位移增长,导致入渗量、入渗补给系数和平均入渗率整体随坡度增大而呈幂函数增加,但当坡度25°时,因径流势能沿坡面方向分量增加,径流流速加快,上述入渗特征参数略有降低;(4)由于降雨量在植被生长周期内呈下降趋势,很大程度上导致植被对入渗特征的影响受控于降雨量,土壤入渗量表现出随着植被盖度的增加呈幂函数显著下降的趋势。总体而言,降雨特征和坡度是影响土壤入渗的主要因素,且土壤入渗特征参数可表示为降雨过程参数和坡度的综合幂函数方程;在入渗补给系数较高的情况下,植被覆盖对土壤入渗特征的影响减弱。研究结果对于坡面尺度降雨径流调控机制和生态水文过程研究具有重要意义。     

降雨因子对沂蒙山区不同土地利用方式径流小区产流产沙的影响

[目的]研究降雨量、降雨强度、降雨历时等降雨因子对沂蒙山区小流域不同土地利用方式径流小区产流产沙的影响,为该区水土流失防治、水土保持规划、生态建设等提供参考。[方法]对沂蒙山区不同土地利用方式径流小区(自然荒坡和荞麦、野生牧草和花生)两两对照并且进行连续3a的定位观测,对观测数据进行统计分析和显著性检验。[结果](1)降雨量与各径流小区产流量的相关性显著(p0.01),与荞麦小区和花生小区产沙量的相关性显著(p0.01),与自然荒坡小区和野生牧草小区的产沙量相关性较差。(2)平均降雨强度(I)与各径流小区的产流量和产沙量的相关性均不显著。10 min最大降雨强度(I10)和30min最大降雨强度(I30)与各径流小区产流量以及荞麦小区、花生小区的产沙量均具有较好的相关性,其中30min最大降雨强度(I30)的相关性最好。(3)降雨历时与荞麦径流小区的产流量和产沙量相关性显著(p0.01),与其他径流小区的产流量和产沙量虽皆呈正相关但相关性均不显著。[结论]降雨量(P),10min最大降雨强度(I10),尤其是30min最大降雨强度(I30),降雨历时等降雨因子在沂蒙山区坡面产流产沙过程中都起到了不同程度的作用,不同的土地利用方式也是影响坡面产流产沙的重要因子。     

黔西高原地区降雨侵蚀力的简易算法

[目的]对黔西高原地区侵蚀性降雨特性进行分析并探索降雨侵蚀力的简易算法,为该区土壤侵蚀预报模型的建立提供理论依据。[方法]利用径流小区观测法,基于毕节小区2012—2014年53次降雨过程资料进行分析。[结果](1)降雨量(P)和最大60min降雨动能(E60)是影响坡面产流、产沙的两个主要因子。坡面产流、产沙与最大60min雨强(I_(60))显著相关;(2)坡面产流产沙与二元复合因子的相关系数显示,EI_(60),PI_(60)和I30I_(60)是影响坡面产流、产沙的3类主要降雨复合指标,EI30和EI_(60)与坡面产流产沙的相关系数间相差较小;(3)基于坡面产流、产沙与降雨单指标和降雨复合指标的相关关系,确定了简易算法的参数。[结论]基于可比性,以R=EI30作为参照值对3种简易算法的结果进行决定系数和偏差率比较后,得到研究区便捷、快速的降雨侵蚀力简易算法为:R=0.344(PI_(60))。     

红壤区裸露坡地不同类型次降雨的产流产沙规律

为探究红壤区裸露坡地在不同类型次降雨下的产流产沙规律,研究收集长汀县水土保持科教园红壤裸露坡地径流小区2013年1月至2020年12月共388场降雨—径流—土壤侵蚀观测资料,采用K-means将降雨划分为4类进行分析。结果表明:(1)主要降雨类型有A(短历时、大雨强、小雨量、低频次)、B(长历时、小雨强、大雨量、中频次)、C(中等历时、小雨强、小雨量、高频次)3类,B、C为研究区主要产流产沙来源,贡献85%以上的径流和土壤侵蚀量。(2)次降雨径流深及土壤侵蚀量与降雨量(P)、最大30 min雨强(I₃₀)和降雨动能(E)呈线性正相关,与降雨侵蚀力(EI₃₀)呈幂函数关系。但降雨特征对产流产沙的总解释度小于65%,且随着降雨历时的增加而减小。(3)降雨特征与产流产沙存在3种约束关系,其约束线表明降雨特征对次降雨潜在最大产流产沙的影响。其中,潜在最大径流深主要由P和E决定,潜在最大土壤侵蚀量的上限为800~900 t/hm²。从降雨特征单因子影响、综合影响和约束效应3个方面分析了红壤裸露坡地的产流产沙特征,为红壤区水土流失防治提供了数据基础。     

Upslope inflow,hillslope gradient and rainfall intensity impacts on ephemeral gully erosion

Ephemeral gullies (EGs) are major contributors to sediment loss and land degradation on cultivated lands. However, the topography and rainfall impacts on EG development processes are still unclear, especially on steep loessial hillslopes such as the Loess Plateau. A series of laboratory rainfall simulation experiments were conducted to investigate the impacts of topographic characteristics (3 typical slope gradients (S ): 26.8%, 36.4%, and 46.6%; and 5 upslope drainage areas (A ): 16, 32, 64, 96, and 128 m²) and rainfall intensities (3 representative erosive rainfall intensities 50, 75, and 100 mm hr⁻¹) on EG erosion on a steep loessial hillslope. A large slope adjustable soil pan (8 m‐long, 2 m‐wide, and 0.6 m‐deep) and a side‐sprinkler rainfall simulation system were used in this study. The results showed that soil loss increased when rainfall intensity, slope, and upslope drainage area increased. Upslope topography and inflow had great impacts on downslope EG erosion, and the contribution percentages ranged from 52.2% to 74.1%, from 48.3% to 71.4%, and from 29.5% to 66.7% for the 50, 75, and 100 mm hr⁻¹ rainfall treatments, respectively. Runoff velocities with upslope inflow were 22.7% to 79.4% larger than those without inflow, and the upslope inflow was more effective than rainfall intensity in increasing runoff velocities in EG channels, thus caused more soil erosion. Soil loss equation based on rainfall intensity and AS ² (product of the upslope drainage area and the square of the local slope gradient) was established and validated. The determination coefficient (R ² ) and Nash–Sutcliffe simulation efficiency (E _NS ) were 0.80 and 0.87, which showed satisfactory accuracy. This equation can be used to predict the EG erosion in various topographic and rainfall conditions on steep loessial hillslopes.     

Effect of increasing the time between slurry application and first rainfall event on phosphorus concentrations in runoff

Minimizing slurry phosphorus (P) losses in runoff requires careful management in the context of both soil P surpluses and changing patterns in rainfall. Increasing the time interval between slurry application and the first rainstorm event is known to reduce P loss in runoff although the risk period for elevated P concentrations in runoff can extend for weeks. This study investigated the impact of increasing the time interval between slurry application and first rainstorm event on P concentrations in runoff. Simulated rainfall (40 mm h⁻¹) was applied at 2, 4, 10, 18, 30 and 49 days after dairy slurry was surface-applied to a grassland sward in Ireland. Increasing time to runoff resulted in a decrease in dissolved reactive P concentrations from 5.0 to 1.0 mg P L⁻¹ and a P signal in runoff for 18 days. Beyond 18 days, elevated P concentrations were observed in runoff collected from natural rainfall that preceded the day 49 rainstorm event. A published surface phosphorus and runoff model (SurPhos) was used to understand the slurry P dynamics controlling P interactions with runoff. Dissolved reactive P in runoff was predicted with accuracy by SurPhos, R² = .89. The SurPhos model implied that slurry P mineralization occurred during the experimental period that resulted in a small spike in P concentrations beyond the defined risk period. This study shows that the experimental data have the potential to be extrapolated to different weather scenarios using SurPhos and could test when and where slurry P could be most safely spread.     

Predicting runoff from semi-arid hillslopes as source areas for water harvesting in the Sierra de Gador, southeast Spain

The effectiveness of water harvesting systems collecting surface runoff form rangeland hillslopes in semi-arid regions is difficult to predict, since the hydrological response at the outlet depends on the heterogeneity of hydrological processes. The lack of continuous runoff pathways, due to the irregular spatial patterns of soil properties and the variety of antecedent soil moisture conditions directly influence runoff generation and control discharge into the water harvesting cisterns. The aim of this paper is to evaluate the effectiveness of semi-arid hillslopes in generating runoff for water harvesting systems. Runoff was estimated by the STREAM expert-based model which was applied to three semi-arid hillslopes (0.4 to 6 ha). On the one hand the STREAM model rules were adapted to the regional conditions i.e. an antecedent precipitation index was adjusted to local soil moisture conditions and the rainfall duration was defined as the total rainfall event quantity and the effective rainfall duration (P_tot/t_eff). On the other hand, the distribution of rock outcrop and vegetation cover along the slopes was used to define homogeneous hydrological units. Final infiltration capacities were attributed to these hydrological units based on values found in the literature. The prediction performances are acceptable for the three water harvesting systems with an RMSE of 13.9 m³. It was shown that the rainfall/runoff model was more sensitive to the duration of the storm than to the antecedent soil moisture conditions. The use of a unique set of hydrological parameters for the three water harvesting systems on representative hillslopes allows the runoff prediction from any rangeland hillslope within the same region. Furthermore, the spatial patterns of soil surface characteristics are crucial for collecting runoff at the outlet of the system. Model runs demonstrated that degradation of vegetation and sealing of very small areas within flow paths can lead to an increase of annual runoff by as much as a factor two.     

基于降雨量和降雨时间的月降雨侵蚀力简易算法——以陕北黄土丘陵沟壑区为例

 降雨侵蚀力简易算法是较大尺度应用USLE/RUSLE进行土壤侵蚀评价研究的必要内容。基于降雨量和降雨时间建立月降雨侵蚀力计算模型,并以陕北黄土丘陵沟壑区为例,进行模型的拟合。结果表明:随着自变量中降雨量和降雨时间表示方式的改变,模型的拟合优度表现出明显的差异;对于不同因变量而言,以ΣEI30(或lg(ΣEI30))和以ΣEI10(或lg(ΣEI10))为因变量的模型拟合优度在整体上比较接近甚至相同,而以ΣE60I10(或lg(ΣE60I10))为因变量的模型拟合优度在整体上略低;就尺度效应而言,在时间尺度上,整个汛期的模型拟合优度低于1个月份或多个月份模型的拟合优度,在空间尺度上,区域模型中的拟合优度低于至少1个流域的模型拟合优度;在实际应用中,可以选择以ΣEI30为因变量的月降雨侵蚀力公式对该区域进行土壤侵蚀评价。     

Influence of Soil Properties and Manure Sources on Phosphorus in Runoff during Simulated Rainfall

Runoff from agricultural fields amended with animal manure or fertilizer is a source of phosphorus (P) pollution to surface waters, which can have harmful effects such as eutrophication. The objectives of this study were to evaluate the impact of soil P status and the P composition of manure sources on P in runoff and characterize the effects of manure sources on mass loss of dissolved reactive P, total dissolved P, and total P in runoff. Soil boxes set at 5% slopes received 7.5 cm h^?1 of simulated rainfall for 30 min. Study soils included a Kenansville loamy sand (loamy siliceous subactive thermic Arenic Hapludults, a Coastal Plain soil) and a Davidson silt loam (kaolinitic thermic Rhodic Kandiudults, a Piedmont soil). Soil test P concentrations ranged from 16 to 283 mg P kg^?1. Sources of P included broiler litter, breeder manure, and breeder manure treated with three rates of aluminum sulfate (Al₂(SO₄)₃) 0, 3.9, and 7.8 kg m^?2, di-ammonium phosphate (DAP), and an un-amended control. All manure sources were surface applied at 66 kg P ha^?1 without incorporation. Water extractable P represented an average of 10 ± 6% total P in manure. Runoff samples were taken over a 30-min period. Piedmont soil contained greater amounts of clay, aluminum (Al), and iron (Fe) concentrations, and higher P sorption capacities that produced significantly lower dissolved reactive P, total dissolved P, and total P losses than the Coastal Plain soil. Runoff P loss did not differ significantly for low and high STP Coastal Plain soils. Water extractable P in manures accounted for all dissolved reactive P lost in runoff with dissolved reactive P correlating strongly with water extractable P concentration (r² = 0.9961). Overall, manures containing the highest water extractable P concentrations contributed to the largest amounts of dissolved reactive P in runoff. Manure treated with 3.9 and 7.8 kg m^?2 of Al₂(SO₄)₃ (alum) decreased dissolved reactive P in runoff by 29%. While this soil box runoff study represents a worst-case scenario for P loss, highly significant effects of soil properties and manure sources were obtained. Management based on these results should help ameliorate harmful effects of P in runoff.     

香根草植物篱带宽对紫色土坡地产流产沙的影响

为研究植物篱篱带宽度对紫色土坡地产流产沙过程的影响,寻求有效控制水土流失的最优植物篱带宽度,采用人工模拟降雨试验对3种篱带宽度(20,30,40cm)、不同雨强(30,60,90mm/h)下的紫色土坡地产流产沙过程进行研究。结果表明:(1)植物篱能有效延缓紫色土坡面产流时间,坡面产流量与篱带宽度能拟合为二次方程(R2=0.99)。随篱带宽度的增大,流速减小,且篱带内部的流速下降最明显,流速变化曲线波动幅度变小。(2)植物篱在产沙过程前期有效抑制坡面产沙量的增长,坡面产沙量随篱带宽度的增大而减少,且当雨强为30,90mm/h时,二者拟合的二次方程R2达到0.99。(3)篱带宽度对产流、产沙量的影响均为极显著。30mm/h雨强下、宽度为30cm的篱带可达到显著的减流减沙效益,是能有效控制水土流失的最优植物篱带宽度。