降雨条件下地表糙度对片蚀的影响及其变化

为了进一步明确地表糙度在片蚀过程中的效应,该文通过室内人工模拟降雨的方法,就场降雨和连续降雨条件下,地表糙度对片蚀的影响及其变化进行了研究。结果表明,场降雨条件下,实施人为管理措施坡面的径流与产沙量均低于对照坡面;在雨强0.67 mm/min条件下,随地表糙度的增加,径流量与侵蚀量呈先减小、后趋于稳定的变化趋势;而在雨强1.63 mm/min条件下,随地表糙度的增加,径流量与产沙量却呈一直减小的变化趋势。在雨强0.67 mm/min条件下,耙耱地、人工掏挖和等高耕作坡面的地表糙度均呈减小的变化趋势,而人工锄耕坡面的地表糙度呈增加的变化趋势;在雨强1.63 mm/min条件下,人工掏挖和等高耕作坡面的地表糙度呈减小的变化趋势,人工锄耕、耙耱地坡面的地表糙度却呈增加的变化趋势;对照坡面地表糙度的变化,与耙耱地相反。连续降雨条件下,在前二次降雨作用下,坡面的径流量与产沙量随地表糙度的增加而逐渐减小,且均低于对照坡面;在第三次降雨条件下,径流与侵蚀产沙量变化较为复杂,且实施人为管理措施坡面均高于对照坡面。不同降雨条件下,实施人为管理措施坡面地表糙度对片蚀具有一定的抑制效应,且坡面片蚀的发展与地表糙度间的变化表现出相应的互动作用。该文研究结果为揭示地表糙度的侵蚀特征提供了一定的理论依据,同时也为黄土高原坡耕地的水土流失治理奠定理论基础。     

降雨条件下耕作方式对地表糙度的溅蚀效应

地表糙度是影响坡耕地土壤侵蚀的主要因素之一,为了进一步明确耕作方式对地表糙度的侵蚀效应,该文通过室内人工模拟降雨的方法,就单雨强与组合雨强条件下耕作方式对溅蚀的作用以及地表糙度的变化进行了研究。结果表明,从对照坡面,经耙耱地、人工锄耕、人工掏挖到等高耕作方式的坡面,在雨强0.62 mm/min条件下,不同耕作方式坡面向上坡溅蚀量呈先增加再减小的变化,向下坡和总溅蚀量均呈先增加再减小最后增加的变化;除耙耱地外,其他耕作方式坡面的地表糙度呈减小的变化。在雨强1.53 mm/min条件下,不同耕作方式坡面向上坡、向下坡和总溅蚀量均呈先增加再减小最后增加的变化;地表糙度与对照坡面相反,均呈增加的变化。组合雨强条件下,随降雨强度的增加,耙耱地总溅蚀量与地表糙度呈一直增加的变化趋势;其他耕作方式下,随降雨强度的增加,坡面总溅蚀量呈先增加后减小的变化趋势,地表糙度却呈先减小后增大的变化。这为揭示地表糙度的侵蚀特征提供了一定的理论依据,同时也可服务于黄土高原坡耕地的水土流失治理。     

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70 mm/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\     

Runoff,erosion and sediment particle size from smooth and rough soil surfaces under steady rainfall-runoff conditions

The responses of runoff and erosion to soil surface roughness (SSR) have been extensively studied in the past decades; however, most of these studies were conducted at the early stage of rainfall, whereas few studies were specifically conducted during steady runoff conditions. In this study, runoff, soil losses and sediment particle sizes from smooth and rough surfaces were measured after surface runoff stabilisation to improve the understanding of the relationship between SSR and soil erosion. A cascade of two independent soil boxes in which the runoff samples from upslope and downslope boxes can be collected independently or together was used to perform the experiments. The upslope box supplied runoff to the downslope study box. Three rainfall intensities of 50, 75 and 100 mm/h were applied. The results suggest that SSR has a significant effect on soil erosion when runoff reaches a steady state. Although the difference in the runoff rate was small between the rough and smooth surfaces, the sediment rate and concentration of particles were significantly lower for the rough surface than for the smooth surface. Through analysing the particle size distribution (PSD) of sediment, we found that selective sediment delivery is an important reason for the soil erosion reduction by SSR. The rainfall intensity decreased the difference in the sediment rates between the smooth and rough surfaces. The extra inflow increased the runoff rates, sediment rates and concentration rates for both the smooth and rough surfaces; however, the increasing degrees of the runoff rate, sediment rate and concentration rate had significant differences between the rough and smooth surfaces. A stepwise multiple regression showed that significant linear relationships existed between one or more PSDs of 20–50, 50–100, 100–250 and 1000–2000 µm and the sediment rate.     

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.     

雨强和坡度对红壤坡耕地地表径流及壤中流的影响

地表径流和壤中流是坡面重要水文过程,雨强和坡度是影响坡面地表径流和壤中流产流主要因素。为研究降雨强度和地表坡度对坡耕地地表径流和壤中流的影响,该文采用人工模拟降雨试验法,在长3.0 m、宽1.5 m、深0.5 m土槽,设计4个不同坡度(5°、10°、15°、20°)和3个不同雨强(30、60、90 mm/h)对红壤坡耕地地表径流及壤中流产流过程进行模拟试验。结果表明:1)壤中流开始产流时间滞后于地表径流,降雨强度从30到90 mm/h,地表径流、壤中流产流开始时间均随雨强增大而减小,壤中流比地表产流开始滞后时间随着雨强增大先增大后趋于稳定;2)地表径流强度随雨强增大而增大,壤中流初始径流强度随雨强增大而增大,不同雨强下壤中流径流峰值相近;3)地表径流和壤中流产流过程曲线有明显差异,地表径流产流过程线先增大后趋于稳定,壤中流产流过程线呈抛物线型即先增大后减小;4)从5°到20°,地表产流开始时间随坡度增大而减小,壤中流产流开始时间随坡度增大先减小后增大;5)从5°到20°,地表径流强度先增大后减小,10°为转折坡度,壤中流产流峰值随坡度增大而减小,并且随着坡度增大达到壤中流峰值时间不断减小。     

Interrelationship among slope steepness,tillage practice and rainfall properties with surface runoff and soil loss on Mollisols in Northeast China

ABSTRACT

Soil erosion and rainfall-induced runoff are well studied yet remain somewhat unpredictable from one natural rainfall to the next, due to interactions between erosion parameters. This study quantified the relationship between annual (2011–2016) and individual (2016) rain events with overland flow (runoff) and soil loss in China’s northern ‘corn-belt’. Two tillage practices and slopes were evaluated (no-till and conventional till, 5° and 7° slopes). Results showed 54 rainfall events for a total of 394 mm precipitation ranging between May and October 2016. Runoff occurred 13 times in the conventional till with 7° slope, accounting for 25.9% of the precipitation volume and caused 15.6 t ha^?1 erosion. It occurred twice in the no-till with 5° slope plot and caused 0.2 t ha^?1 erosion., Thus the no-till with 5° slope treatment is the best tillage system to protect soil in Mollisols in Northeast China. Broad analysis coupled with a detail review of three rainfall events demonstrates that water either runs off plots quickly or rapidly infiltrates while sediment moves in a pulsing manner.     

Hydraulic conductivity, residue cover and soil surface roughness under different tillage systems in semiarid conditions

The objective of this study was to investigate the effect of tillage and cropping system on near-saturated hydraulic conductivity, residue cover and surface roughness to improve soil management for moisture conservation under semiarid Mediterranean conditions. Three tillage systems were compared (subsoil tillage, minimum tillage and no-tillage) under three field situations (continuous crop, fallow and crop after fallow) on two soils (Fluventic Xerochrept and Lithic Xeric Torriorthent). Soil under no-tillage had lower hydraulic conductivity (5.0 cm day⁻¹) than under subsoil tillage (15.5 cm day⁻¹) or minimum tillage (14.3 cm day⁻¹) during 1 of 2 years in continuous crop due to a reduction of soil porosity. Residue cover at sowing was greater under no-tillage (60%) than under subsoil or minimum tillage (<10%) in continuous crop. Under fallow, residue cover was low (10%) at sowing of the following crop for all tillage systems in both soils. Surface roughness increased with tillage, with a high value of 16% and decreasing following rainfall. Under no-tillage, surface roughness was relatively low (3–4%). Greater surface residue cover under no-tillage helped conserve water, despite indications of lower hydraulic conductivity. To overcome the condition of low infiltration and high evaporation when no-till fallow is expected in a cropping sequence, either greater residue production should be planed prior to fallow (e.g. no residue harvest) or surface tillage may be needed during fallow.     

The role of soil surface conditions in regulating runoff and erosion processes on a metamorphic hillslope (Southern Spain): Soil surface conditions,runoff and erosion in Southern Spain

This study presents the results of an analysis into the role of soil surface conditions in the regulation of soil hydrology and erosive processes at one hillslope under dry Mediterranean climatic conditions. The methodology was based on the analysis of hillslope surface components and their hydrological and erosive function on a patch to scale by means of rainfall simulation and experimental plots. The results showed the existence of a complex eco-geomorphological system composed of a multitude of vegetation patches distributed at random on the hillslope, and where the presence of different surface conditions on the soil can have a sizeable influence on hydrological and erosive behavior. From the hydrological point of view, the runoff generation mechanisms follow a seasonal pattern depending on the moisture of the soil with a different spatial condition, with frequent hydrological disconnections between parts of the hillslope, as in other Mediterranean mountainous regions. Soil surface rock fragments, the layout of tussocks intra-hillslope and previous soil moisture as dynamic control factors in the hydrological and erosive processes are all important.