黄土区坡耕地耕作对浅沟径流产沙及其形态发育特征的影响

为研究耕作对浅沟径流产沙及形态发育特征的影响,在野外调查的基础上,设计坡度(15°、20°、25°)、雨强(1.0、1.5、2.0 mm/min)及放水流量(7.53~23.45 L/min)3个处理,采用室内模拟降雨和放水冲刷的方法,测定了不同处理下浅沟径流量、产沙量。结果表明:1)2种浅沟水流均为紊流,耕作使浅沟水流雷诺数和弗劳德数分别减小0.95%~30.77%、2.64%~39.14%,阻力系数和糙率系数分别增加4.01%~58.82%、0.88%~27.87%;2)试验条件下,耕作使浅沟土壤剥蚀率增大9.48%~37.87%,未耕作与耕作浅沟土壤剥蚀率分别与坡度—流量交互作用、雨强—坡度交互作用呈极显著线性关系,土壤剥蚀率与径流剪切力、径流功率及单位径流功率均呈显著的线性关系,未耕作浅沟发生剥蚀的临界剪切力、临界功率及临界单位径流功率分别为17.576 N/m2、5.036 W/(m2·s)、0.0381 m/s,耕作浅沟为10.585 N/m2、3.544 W/(m2·s)、0.0277 m/s;3)耕作使浅沟宽度增加1.98%~31.79%,浅沟面积增大0.84%~32.03%,下切深度降低2.82%~26.67%;4)耕作使浅沟土壤侵蚀量增加0.91%~22.80%,未耕作和耕作浅沟土壤侵蚀量分别占坡面土壤侵蚀总量的44.09%~74.16%和42.44%~56.44%,与雨强—流量交互作用均呈极显著的线性函数关系。结果可为该区浅沟侵蚀预测模型的建立及农业生态环境安全与保护提供科学依据。     

Characteristics and factors controlling the development of ephemeral gullies in cultivated catchments of black soil region, Northeast China

Ephemeral gully erosion is an important process in the black soil region, Northeast China and can be responsible for severe damage to agricultural lands. However, little research on gully formation in this area has been published. The study described in this paper attempted to quantify soil losses, the spatial distribution and morphology of the gullies, and the factors that control their development. Ephemeral gullies were measured in spring and summer of 2005 in two small catchments. The critical periods for ephemeral gully formation were late spring and summer in the study area. Mean soil losses due to ephemeral gully erosion were 0.40 and 0.43 kg m⁻² year⁻¹ for only croplands despite low slope gradients, and this loss is above the tolerable erosion rates of 0.20 kg m⁻² year⁻¹. The erosion rates were greater in spring because the topsoil thawed before deeper layers, reducing infiltration into the soil, and the bare vegetation cover provided no barriers to surface flow. In contrast, summer erosion occurred primarily in response to intense rain events. Development of the gullies was promoted by freeze-thaw cycles in spring and was affected by the type of agricultural operations and crops in summer. A linear regression model for the prediction of ephemeral gully length at the catchment level was established using field data, and although it did not successfully predict the length of individual gullies, it explained 55% of the variation in ephemeral gully length.     

Rill and gully development during an extreme winter runoff event in Norway

Erosion on agricultural fields in Norway has earlier been reported to be mainly sheet and minor rill erosion. Exceptional rainfall events during January and February (230% of 30 years monthly mean) in 1990 led to extreme runoff and widespread erosion also on areas normally not considered to have a high erosion risk. This study presents the results of a field survey in three counties where rills and ephemeral gullies were measured after this event. Shifting weather conditions with freezing and thawing had given frozen subsoil. Topsoil conditions varied from ice- and snow-covered surface to thawed surface with frozen subsoil. In one of the areas with a high clay content, only the upper topsoil layer was unfrozen during this event. Extended sheet erosion and smaller rills occurred. In the southernmost locations, more of the topsoil profile was unfrozen. Combined with a high silt/sand content, more severe rilling and ephemeral gullies developed. Gullies developed down to the depth of the drainpipes in all locations. This erosion equals soil losses of more than 100 tons ha⁻¹ or 8–9 mm soil lost from the entire field area. Different mechanisms for gully development were registered. Gullies developed as enlarged rills with headward migration and sidewall sloughing. Knickpoints in the slope could also lead to gully development. Concentrated water flow entering the field from farmyards, roads, neighbouring fields and woods could be the starting point for uncontrolled rilling and ephemeral gullying. The combination of frozen subsoil, saturated soil with low strength and intense rainfall led to gully development also on areas with gentle slopes, especially sandy soils. Management practices like crop cover, tillage and lack of surface water control highly influenced the development of gullies.     

On-site effects of concentrated flow erosion in vineyard fields: some economic implications

Although it is well known that ephemeral gully erosion is a process of a recurrent nature and its contribution to total sediment production is far from negligible, there is a gap in the assessment of changes that the ephemeral gullying cycle produces in the fields' landscape and in the general economic balance of farms (the cost of erosion). The present paper applies a method for assessing the topographic changes produced by concentrated flow erosion, mainly ephemeral gullies, and their filling by farmers. The method is based on the comparison of multi-date detailed topographic data (digital elevation models, DEMs). In the case study, 0.20-m spatial resolution DEMs of March 2000, June 2000 and July 2002 were used to assess the changes in a vineyard field (located in the Penedès region, Catalonia, NE Spain), in which there are hillside ditches (broadbase terraces) that function as sediment traps to avoid major soil loss. The study period was divided into two, according to an extreme rainfall event that occurred on 10 June 2000, in which 214.6 mm fell in 1 day, representing 44% of the annual precipitation. This storm, with a return period in the area of 105 years, displaced 282±4 Mg ha⁻¹ of sediment, 58% of which was due to concentrated surface runoff that caused considerable surface lowering (ephemeral gullies) of up to 0.4–0.5 m deep in some parts of the field. During the second period, about 208±3 Mg ha⁻¹ of soil and sediment deposited in the hillside ditches was used to fill ephemeral gullies. The general sediment/soil balance at the locations where ephemeral gullies recurrently occur is negative (−74±3 Mg ha⁻¹), indicating that recurrent concentrated surface runoff is producing a progressive surface lowering of those zones. The research also assessed the efficiency of the hillside ditches as sediment traps. A total of 113±2 Mg ha⁻¹ was deposited in these structures during the period March 2000–June 2000 (in which the extreme rainfall event occurred), which represents 54% of the material used to fill ephemeral gullies in the period June 2000–July 2002. Finally, the cost of erosion, evaluated as the cost of the operations necessary to redistribute the sediment/soil over the field and to repair the hillside ditches, represented 5% of the income of the farms.     

降雨和汇流条件下浅沟侵蚀过程试验研究

[目的]探究含沙水流汇入对含有浅沟微地形的裸土和草地坡面的侵蚀产沙过程的影响,为该地区浅沟侵蚀治理提供理论依据,并为坡沟系统的土壤侵蚀模型建立奠定基础。[方法]通过降雨和放水相结合的野外模拟试验和人工建筑的浅沟模型开展研究。[结果]含沙水流汇入裸土浅沟坡面的侵蚀量增加了15%～58%,而对草地浅沟坡面的侵蚀影响不显著,说明草地恢复对于减少由汇流作用的侵蚀具有显著效益。试验条件下裸坡和草地坡面泥沙浓度都在产流开始时达到最大然后逐渐降低,最后达到稳定,然而含沙水流汇入使得泥沙浓度达到稳定所需的时间延长。含沙水流汇入能够显著增加浅沟发育速度,特别是浅沟沟宽和下切深度增加明显,草地恢复可以显著减缓浅沟的下切侵蚀,进而减缓浅沟的发育速度。对于裸土和草地浅沟坡面,含沙水流汇入显著增加了浅沟部位流速,尤其是草地浅沟部位各坡段流速平均增幅达到了55%。[结论]增加含沙水流汇入会显著增加裸坡坡面上的浅沟侵蚀量和浅沟的发育速度,而对草地坡面上浅沟的侵蚀和发育影响不显著。     

Study of ephemeral gully erosion in a small upland catchment on the Inner-Mongolian Plateau

Ephemeral gully erosion is an important soil erosion process on the Inner-Mongolia Plateau in North China, and although its damage is very intense, little research on the area has been published. In this paper, a global positioning system (GPS) is used to measure the morphology of ephemeral gullies in a small catchment, the Inner-Mongolia Autonomous Region. First, this paper presents the characteristics of ephemeral gullies and soil loss due to ephemeral gully erosion. The network of ephemeral gullies takes on the shapes of tree branches, and there are 16 hole-ephemeral gullies in the middle of the ephemeral gullies. An average gully length of about 19.6 m ha⁻¹ and an average soil loss of 8.8 m³ ha⁻¹ due to ephemeral gully erosion were measured. Second, soil erosion influences crop production in cropland and combinations of vegetation in fallow. The difference between vegetation in the middle of ephemeral gullies and in other places is very obvious. Third, this paper discusses hole-ephemeral gullies that are holes locating in the middle of ephemeral gullies whose widths and depths are more than 0.5 m (Fig. 6) for the first time. The relationship between local hill slope gradient S (m m⁻¹) and upslope contributing area A (ha) can be expressed as S = 0.064A^−0.375 and may be a key indicator for determining the position of existing hole-ephemeral gully heads and for predicting where hole-ephemeral gullies could form in the small watershed on the Inner-Mongolian Plateau.     

Morphological Similarity of Channels: From Linear Erosional Features (Rill,Gully) to Alpine Rivers

The geometric characteristics of incised features such as channels, rills, ephemeral gully, gully, represent the erosional transport regime and the fluvial dynamic equilibrium, and thus it is critical for the understanding of the long‐term evolution of natural, agricultural, and anthropogenic landscapes. This paper examines the morphological similarity of channelized erosion in two different environments such as Alpine landscapes and cultivated hillslopes. The first dataset comprises six rivers in the Italian Alps, three in the Carnia region and three in the Dolomites, where erosion is mainly the effect of discharges with high sediment loads or landslides and debris flows. The agricultural areas dataset includes rills, ephemeral gullies, and gullies surveyed in literature. This research highlights that the eroded volume in Alpine rivers is in line with that of agricultural landscapes or badlands around the world. Dolomites rivers of colluvial origin, flowing on soils that are not particularly deep and subject to natural disaggregation, tend to behave similarly to ephemeral gullies. Contrarily, channels that exhibit evident alluvial morphologies and coarse grain sizes are more similar to gully erosion. At different spatial scales, the results demonstrated that length–volume equations calibrated on rills, ephemeral gullies, gullies and badlands, might be feasible also for Alpine channels. The research areas present soils and bedrock lithology that differs from those in literature, thus suggesting that the morphology of linear erosion is independent of the intrinsic soil characteristics. Differences emerged between Dolomites and Carnia rivers: this highlights the importance of taking into account in future analyses other forcing factors (e.g. climate) on land degradation processes. Copyright © 2017 John Wiley & Sons, Ltd.     

Ephemeral gully recognition and accuracy evaluation using deep learning in the hilly and gully region of the Loess Plateau in China

Ephemeral gullies are widely distributed in the hilly and gully region of the Loess Plateau and play a unique role in the slope gully erosion system. Rapid and accurate identification of ephemeral gullies impacts the distribution law and development trend of soil erosion on the Loess Plateau. Deep learning algorithms can quickly and accurately process large data samples that recognize ephemeral gullies from remote sensing images. Here, we investigated ephemeral gullies in the Zhoutungou watershed in the hilly and gully region of the Loess Plateau in China using satellite and unmanned aerial vehicle images and combined a deep learning image semantic segmentation model to realize automatic recognition and feature extraction. Using Accuracy, Precision, Recall, F1value, and AUC, we compared the ephemeral gully recognition results and accuracy evaluation of U-Net, R2U-Net, and SegNet image semantic segmentation models. The SegNet model was ranked first, followed by the R2U-Net and U-Net models, for ephemeral gully recognition in the hilly and gully region of the Loess Plateau. The ephemeral gully length and width between predicted and measured values had RMSE values of 6.78 m and 0.50 m, respectively, indicating that the model has an excellent recognition effect. This study identified a fast and accurate method for ephemeral gully recognition in the hilly and gully region of the Loess Plateau based on remote sensing images to provide an academic reference and practical guidance for soil erosion monitoring and slope and gully management in the Loess Plateau region.     

雨强和坡度对黄土陡坡地浅沟形态特征影响的定量研究

浅沟形态特征是建立陡坡地坡面浅沟侵蚀预报模型的基础。为了定量研究黄土陡坡地浅沟形态特征,在长8 m、宽2 m、深0.6 cm的试验土槽上制作了雏形浅沟,设计了2个降雨强度(50、100 mm/h)和3个浅沟发生的典型坡度(15°、20°、25°),利用模拟降雨和径流冲刷(10 L/min)相结合的试验方法定量分析了黄土陡坡地的浅沟形态特征。结果表明:降雨强度和坡度的增加均加快了坡面浅沟侵蚀过程并使浅沟沟槽宽度和深度不断增加,25°和100 mm/h降雨强度下的浅沟沟槽平均宽度和深度比15°和50 mm/h降雨强度下的分别增加1.40和0.61倍。根据测针板法得到的3 cm×10 cm精度的地表高程值数据,在Surfer软件中生成不同试验处理下的地面数字高程模型(DEM,digital elevation model)及水流流路图等,发现坡度的增加使两侧坡面细沟汇入浅沟沟槽的坡长增大,而降雨强度的增加则导致浅沟沟槽两侧坡面细沟汇入浅沟沟槽的坡长缩短,同时,沟道密度、地面割裂度和浅沟复杂度均随着降雨强度和坡度的增加而呈现增大的趋势,三者分别变化于0.74~1.48 m/m2、0.13~0.29和1.64~2.84之间,而不同降雨强度和坡度条件下浅沟沟槽宽深比变化于0.65~1.27之间。基于不同试验处理下的DEM,根据相邻格网关系在水平方向上计算方向导数后发现,方向导数格网等值线图可以有效地反映坡面浅沟和细沟的长度、表面积及侵蚀最严重的浅沟沟底位置。     

甘肃省小陇山林区降雨型浅层滑坡汇水面积-坡度关系及其影响因素

沟头发生侵蚀的地形临界模型可有效预测侵蚀沟的形成条件,浅层滑坡失稳形成的洼地也是沟头形成的方式之一。为探究浅层滑坡临界起动模型的特点,以甘肃省天水市小陇山林区的降雨型浅层滑坡为研究对象,运用汇水面积-坡度关系,构建临界起动模型,与黄土高原典型侵蚀沟(浅沟、切沟)的临界起动模型进行对比分析,并探讨土地利用类型、植被类型和土壤质地对该模型的影响。结果表明:(1)浅层滑坡临界起动模型为S=3.50A_s^-0.34,其侵蚀阈值为3.50,大于黄土高原典型浅沟(0.96)和切沟(1.54)的侵蚀阈值。研究区浅层滑坡一般发生于土层较薄的陡坡地带,其平均坡度(S=1.26)大于浅沟(S=0.35)与切沟(S=0.46),单位汇水面积(A=89.08 m²/m)小于浅沟(A=920.93 m²/m)和切沟(A=1 129.82 m²/m)。(2)汇水面积与坡度平方的乘积(AS²)代表了沟头产生侵蚀的能量指标值。研究区浅层滑坡AS²值在269.1~5 703.2 m²,平均值为1 772.97 m²,黄土高原浅沟AS²值在4.74~892.66 m²,切沟在41~814 m²,启动能量值方面,浅沟<切沟<浅层滑坡。(3)土地利用类型、植被类型和土壤质地通过影响土壤的抗冲力、渗透性和黏粒含量,从而对浅层滑坡的起动难易程度产生影响。在不同的土地利用方式中,农地最易发生侵蚀,其次是林地。油松林附近浅层滑坡的抗侵蚀能力高于日本落叶松林。研究结果为探究浅层滑坡的起动条件提供理论依据。     

黄土高原沟壑丘陵区沟道侵蚀与洞穴侵蚀特征

[目的]通过对黄土高原沟壑丘陵区内的沟道侵蚀和洞穴侵蚀进行特征分析,为该地区开展水土保持工作提供数据支持和决策依据。[方法]以王家沟流域为研究对象,通过资料收集、卫星影像识别和现场调查等方法对流域内沟道侵蚀和洞穴侵蚀状况进行分析。[结果](1)流域内共分布718条沟道和948个洞穴。(2)根据空间位置和地形特点将所有沟道分为冲沟、切沟、干沟、河沟。这4类沟道由于受土壤岩性组成、坡度及人为活动等因素影响,空间分布存在巨大差异。(3)43%的洞穴分布在冲沟中,51%分布在切沟中,6%分布在干沟中。河沟中没有洞穴存在。冲沟和切沟是洞穴形成和发育的主要区域。(4)洞穴沟道的沟长、面积、切深、产流及产沙量都明显大于非洞穴沟道。[结论]在黄土高原丘陵沟壑区,洞穴侵蚀是土壤侵蚀的重要组成部分,并对沟道的发育和扩展起着至关重要的作用。     

东北漫岗黑土区地形因子对浅沟侵蚀的影响分析

浅沟侵蚀是坡耕地上重要的产沙方式之一,地形是控制其发生及发展的关键因素。通过对东北漫岗黑土区两个小流域的地形因子和浅沟侵蚀进行相关分析发现,浅沟长度、侵蚀体积与坡面长度呈显著相关,与汇水面积也有较好的相关。根据地形临界理论,确定了研究区浅沟和切沟侵蚀发生的地形临界（S-A）关系：SEG=0.052AEG^- 0.148和SG=0.072 AG^- 0.141,可以用来预测小流域内可能发生浅沟侵蚀以及浅沟向切沟侵蚀转变的部位。在地形分析的基础上,建立了预测浅沟长度的回归模型,交叉验证表明模型对单条浅沟长度的预测误差较大,平均误差37%;而预测浅沟总长度效果较好,预测浅沟总侵蚀量与实测值的误差也只有6%。     

基于RS和GIS的黄土丘陵沟壑区浅沟侵蚀地形特征研究

为了解黄土高原浅沟侵蚀地形特征,基于Qucickbird高分辨率遥感影像和数字高程模型,提取了坡面浅沟及其地形参数,并对浅沟侵蚀的地形特征参数和分布规律进行了统计分析,结果表明：黄土丘陵沟壑区,坡面坡度、长度、坡向以及上坡长度是影响坡面浅沟数量的主要地形要素,而浅沟侵蚀地形特征主要由坡面坡度、坡面长度、上坡长度和汇流面积共同决定;坡面长度与浅沟平均长度呈显著线性关系,坡面坡度与浅沟频度、浅沟坡度与其上坡长度间则均满足二次曲线;发生浅沟侵蚀的上限与下限临界坡度分别介于26～27°和15～20°,临界坡长介于50～80 m;由浅沟坡度的正弦值与汇流面积确定出浅沟分布的临界曲线;阳向坡面的平均浅沟长度小于阴向坡面。基于RS和GIS技术能有效确定浅沟侵蚀地形特征,为黄土区坡面水土流失治理提供了技术支撑。     

黄土区浅沟侵蚀影响因素对其侵蚀速率影响的模拟试验研究

浅沟侵蚀是黄土高原丘陵沟壑区的主要侵蚀类型之一。利用室内模拟降雨与放水相结合的研究方法,对雨强、上游汇水面积、坡度和耕作等因素对浅沟侵蚀的影响进行了初步研究,结果表明:浅沟侵蚀发生的速率与坡度、雨强和汇水面积均呈正相关关系。耕作通过改变表层土壤结构,改变了浅沟侵蚀随雨强、坡度和上游汇水面积与侵蚀速率的响应关系。且在较小坡度坡面上,耕作显著减少由于雨强变化引起的侵蚀变化,但在大坡度和大雨强条件下,耕作对雨强引起的侵蚀变化有加强作用。     

半干旱黄土丘陵沟壑区沟道侵蚀特征研究

利用遥感、地理信息技术和数理统计方法,选择山西省吕梁市王家沟流域为典型区域,系统分析了半干旱黄土丘陵沟壑区沟道侵蚀特征。研究结果表明:在王家沟流域内共有沟道718条,其中冲沟109条,切沟286条,干沟302条及河沟21条。这4类沟道的发育特征和空间分布特征存在巨大差异;沟道侵蚀是王家沟流域内土壤侵蚀的主要形式,沟道侵蚀面积占总侵蚀面积的56.19%;流域内不同坡度范围内土壤侵蚀强度与沟道类型存在紧密联系。同时,人为因素也对黄土丘陵沟壑区的沟道侵蚀具有重要的影响。     

Gully erosion and environmental change: importance and research needs

Assessing the impacts of climatic and, in particular, land use changes on rates of soil erosion by water is the objective of many national and international research projects. However, over the last decades, most research dealing with soil erosion by water has concentrated on sheet (interrill) and rill erosion processes operating at the (runoff) plot scale. Relatively few studies have been conducted on gully erosion operating at larger spatial scales.Recent studies indicate that (1) gully erosion represents an important sediment source in a range of environments and (2) gullies are effective links for transferring runoff and sediment from uplands to valley bottoms and permanent channels where they aggravate off site effects of water erosion. In other words, once gullies develop, they increase the connectivity in the landscape. Many cases of damage (sediment and chemical) to watercourses and properties by runoff from agricultural land relate to (ephemeral) gullying. Consequently, there is a need for monitoring, experimental and modelling studies of gully erosion as a basis for predicting the effects of environmental change (climatic and land use changes) on gully erosion rates.In this respect, various research questions can be identified. The most important ones are:

What is the contribution of gully erosion to overall soil loss and sediment production at various temporal and spatial scales and under different climatic and land use conditions?

What are appropriate measuring techniques for monitoring and experimental studies of the initiation and development of various gully types at various temporal and spatial scales?

Can we identify critical thresholds for the initiation, development and infilling of gullies in different environments in terms of flow hydraulics, rain, topography, soils and land use?

How does gully erosion interact with hydrological processes as well as with other soil degradation processes?

What are appropriate models of gully erosion, capable of predicting (a) erosion rates at various temporal and spatial scales and (b) the impact of gully development on hydrology, sediment yield and landscape evolution?

What are efficient gully prevention and gully control measures? What can be learned from failures and successes of gully erosion control programmes?

These questions need to be answered first if we want to improve our insights into the impacts of environmental change on gully erosion. This paper highlights some of these issues by reviewing recent examples taken from various environments.     

浅沟发育对土壤侵蚀作用的研究

浅沟是坡面细沟侵蚀发生与发展的产物。浅沟形成后,改变了原坡面形态,加速了侵蚀作用过程,增大了土壤侵蚀量。本文采用人工模拟降雨装置在黄土小区上进行试验,结合野外调查,对浅沟侵蚀进行了研究:坡面浅沟的分布密度变化于10～65km/km~2之间;深度变化于0.3～3m之间,并且以1～2m的为多;新倾斜面的倾角变化于10°～30”之间。在相同降雨条件下,浅沟发育坡面的产沙率比未发育浅沟坡面的产沙率要大,二者可相差3倍多。当雨强为1.31mm/min和2.4mm/min时,有浅沟发育坡面的侵蚀量分别增加0.66倍和0.386倍。据估算,由于浅沟的存在,黄土丘陵沟壑区沟间地坡面的侵蚀量将增加25％左右。     

Ephemeral gully erosion by preferential flow through a discontinuous soil-pipe

Subsurface flow through soil-pipes can contribute to ephemeral gully erosion but these soil-pipes are cut-off when tillage fills in the gully. The objective was to determine the effect of flow through discontinuous soil-pipes on ephemeral gully erosion. Experiments were conducted on 150 cm long by 100 cm wide soil beds with an artificial soil-pipe at the upper end that extended 50 cm into the soil immediately above a water-restricting horizon. The combination of rainfall with pipe flow produced extensive (63 kg) soil losses by mass wasting. The mode of mass wasting appeared to be sudden, cataclysmic pop-out failures. Total soil loss by sheet erosion with rainfall and pipe flow combined (13.6 kg) was four times higher than by rainfall alone (3.4 kg). Under rainfall with pipe flow, soil loss by mass wasting was nearly 20 times higher than sheet erosion from rainfall alone. Soil conservation practices that treat surface runoff process alone may be ineffective if subsurface flow is contributing.     

Losses of nitrate-nitrogen in water draining from under autumn-sown crops established by direct drilling or mouldboard ploughing

The leaching of nitrate-N under autumn-sown arable crops was measured using hydro-logically isolated plots, about 0.24 ha in area, from 1984–1988. Fluxes of water and nitrate moving over the soil surface (surface runoff), at the interface between topsoil and subsoil (interflow), and in the subsoil (drainflow) were monitored in plots with mole-and-pipe drain systems (drained plots); surface runoff and interflow only were monitored in ‘undrained’ plots. Half the drained and undrained plots were direct-drilled, and on the other half seedbeds were prepared by tillage to 200 mm. Tillage increased the total leaching loss of nitrate by 21 % compared with direct drilling in drained plots. About 95% or the nitrate moving from the soil was present in the water intercepted by the subsoil drains in these plots. In undrained plots less water and nitrate were collected in total; more of the nitrate was present in interflow on ploughed plots and in surface runoff in direct-drilled land. Losses of nitrate for the whole experiment from 1978-1988 were analysed. This showed that, between the harvest of one crop and the spring application of fertilizer to the next, loss of nitrate-N from ploughed land (L_p) was approximated by L_p=22+Fkg N ha^?1, where F was the autumn fertilizer-N applied. After fertilizer was applied in spring, loss of nitrate-N depended on rainfall such that for 100 mm rainfall about 30% of the fertilizer-N was lost by leaching. About 18% more nitrate-N was lost from direct-drilled land than from ploughed land in spring, but the total loss was generally small compared to that over winter. The apparent net mineralization of organic-N was measured in 1988. In autumn and winter there was little effect of tillage treatment (26 and 31 kg N ha^?1 on direct drilled and tilled plots respectively). However, over the year 83 kg N ha^?1 were mineralized in tilled plots, and 67 kg N ha^?1 in direct-drilled plots. Five factors governing the leaching of nitrate are assessed and this identified that fertilizer nitrogen application to the seedbed of winter sown crops and the mineralization of nitrogen from the residues of the previous crop are the most significant factors for nitrogen leaching in the UK.     

东北典型黑土区侵蚀沟形态及分布特征

东北黑土区是中国最重要的粮食生产基地之一,同时也是中国四大水蚀区之一,其中沟道侵蚀是水蚀发生的主要形式,掌握东北黑土区沟道侵蚀的基本情况,剖析其形态及分布特征,对于分析东北黑土区沟道侵蚀的成因及水土流失治理至关重要。该研究以典型黑土区嫩江县为研究区域,利用航空遥感影像及1∶5万DEM对区域内侵蚀沟进行普查统计,并分析侵蚀沟的沟宽、沟长、纵比降等形态特征,以及海拔、坡度、坡向等地形因素对侵蚀沟分布的影响,为黑土区侵蚀沟的治理提供理论依据。研究结果表明:1)沟道侵蚀主要分布在丘陵区,沟道类型以切沟为主,冲沟影响面积仅次于切沟,研究区以小于500 m的侵蚀沟为主,数量及面积分别占总数的96.67%、61.99%;2)侵蚀沟的沟宽与沟长为正相关,纵比降与沟宽、沟长为负相关;3)坡向对各类型侵蚀沟的分布影响较小,坡度对侵蚀沟的分布有一定影响,细沟和浅沟主要分布在2~6°和6~15°的坡面上,而切沟和冲沟则主要分布在0~2°、2~6°的坡面上,90%以上的细沟和浅沟、80%以上的切沟、冲沟发生在耕地上;4)嫩江县冲沟地形阈值模型拟合表明嫩江县冲沟发生的临界坡度较小,较小的坡度就能对坡面形成冲刷,出现冲沟的发生发育,而模型中主导径流过程的参数数值较小,表明嫩江县冲沟的产生可能受到地下过程的影响。