紫色土坡面降雨侵蚀试验研究

坡面水蚀的主要侵蚀动力来自降雨及其产生的地表径流,将坡面水蚀过程分为降雨侵蚀和径流侵蚀,可以从侵蚀动力、侵蚀特征差异与侵蚀规律等方面研究坡面水蚀过程与机理。应用人工模拟降雨及微小区测定技术,以大田紫色土为研究对象,模拟和测定不同雨强与不同坡度条件下降雨侵蚀过程和侵蚀量,揭示以降雨为主要动力的土壤降雨侵蚀特征和规律。研究结果表明：(1)小雨强(＜67．26 mm/h)下,紫色土坡面降雨侵蚀率具有稳定性,随着降雨历时的增加变化微小；大雨强(106．57 mm/h)下,降雨侵蚀率随降雨历时增加呈上下波动；(2)紫色土降雨侵蚀率与降雨强度呈线性相关,随降雨强度增加而直线增加；(3)降雨侵蚀率与坡度符合二次抛物线关系,随坡度的增加出现临界坡度,且临界坡度随雨强的变化而改变。在中小雨强(18．06～67．26 mm/h)条件下,临界坡度SK的变化范围在17°～19°。在大雨强条件下,临界坡度有逐渐增大的趋势；(4)当坡度与雨强共同影响产沙效应时,坡度对降雨侵蚀的影响较小,雨强能掩盖坡度对产沙的贡献。     

降雨径流汇入背景下受纳水体可溶态Ni和As的动态变化

选取降雨丰沛、降雨径流突出的热带海岛城市海口美舍河市区河段,使用室内分析与野外采样结合的方法开展降雨径流汇入后受纳水体可溶态Ni和As的动态变化研究。结果表明：降雨径流的汇入直接对受纳水体中Ni和As的固液分配产生干扰,且其对受纳水体Ni和As的输入贡献主要依赖悬浮态,可溶态Ni和As输入相对较弱。具体表现为：降雨径流汇入前受纳水体可溶态Ni和As占总质量浓度的比例分别达到55.67%和94.77%。降雨径流汇入后,受纳水体Ni和As发生一系列动态变化,排水口处可溶态Ni和As占比分别达总质量浓度的20.97%和76.92%,可溶态占比明显下降,变化较为剧烈;排水口下游可溶态Ni和As占比也均下降,分别为47.23%和88.38%。对不同降雨情境下的数据分析发现：当降雨量≤10 mm时,雨前干燥期长短是受纳水体可溶态Ni和As动态变化的主要影响因素;当降雨量在10~30 mm时,雨前干燥期长短、雨强峰值出现时间及其大小是受纳水体可溶态Ni和As对降雨径流响应时间及响应程度的主要影响因素;当降雨量≥30 mm时,雨强峰值出现时间是受纳水体可溶态Ni和As动态变化的主要影响因素。降雨径流对受纳水体可溶态Ni和As的影响存在差异,当干燥期短、且存在最大雨强值过高现象时,受纳水体可溶态As受降雨径流影响小,而可溶态Ni受降雨径流影响明显。     

科尔沁沙地降雨特征分析——以奈曼旗为例

了解降水的当前特征及未来的变化趋势对理解气候变化对区域生态系统的影响具有重要的意义。科尔沁沙地是中国北方农牧交错带的典型区域,年降雨量300~500 mm,对气候变化(特别是降水的变化)非常敏感。对科尔沁沙地沙漠化较为严重的奈曼旗1971-2013年的降水资料进行了分析研究。结果表明:(1)该地区多年平均降水量为338.8 mm,5-9月降雨量占全年降水量的(85.32±7.71)%,5-9月降雨量,年降水量1971-2000年经历了先增加后减少的趋势,2001-2013年有缓慢增加的趋势;同时降水量的年际变异性近10年也呈增加的趋势。(2)5-9月降雨量呈先增大后减小的趋势,在7月最大,为104.2 mm,5月和9月最小(分别为32.7 mm和32.8 mm),月降雨量的年际变率均大于49%;生长季内降雨主要以<10 mm的事件为主,占总降雨事件的64.41%,却仅占总降雨量的16.95%;≥30 mm的降雨事件占总降雨事件的10.96%,占到总降雨量的45.93%,且对总降雨量具有决定性的影响。(3)≥5 mm降雨的平均间隔为9.4 d,以1~10 d为主,占到69.5%,10~20 d(19.5%)的次之;≥30 d的发生频率最小,为3.81%,降雨间隔的年际变异性均呈增加的趋势。(4)生长季降雨日数呈减少的趋势,降雨事件降雨量的变异性与生长季降雨量的变化具有相似性,从2001年开始呈增加的趋势。该地区的降雨量年际变异性强,降雨日数的减少和降雨事件降雨量变异性的增加将提高极端干旱事件发生的频率,可能对该地区的生态系统产生严重影响,加剧该地区的沙漠化发展方向。因此,加强气候变化对生态系统影响的研究,可为合理利用土地资源及调整土地管理方式提供理论依据。     

岔巴沟流域次暴雨坡面土壤侵蚀经验模型

坡面土壤流失预测、水保效益评估,无不需要坡面侵蚀模型。本文以岔巴沟流域坡面径流场降雨水文资料为基础,建立了次侵蚀性降雨坡面土壤侵蚀模型、次降雨坡面细沟侵蚀模型,并对各模型的精度进行了分析。结果发现模型具有较好的预报精度,对大侵蚀产沙事件预测很准;坡度、最大10分钟雨强、植被覆盖度是影响次侵蚀性降雨主要因子,坡度、最大10分钟雨强、降雨量是影响细沟侵蚀主要因子,植被覆盖对细沟侵蚀产沙影响很小。     

东北黑土区坡耕地土壤侵蚀对影响因素响应的定量分析

东北黑土区坡地耕作方式多样,侵蚀过程复杂,形成了强烈的水土流失,须加强土壤侵蚀影响因子对产流产沙影响的定量化研究.本文利用2013-2017年东北典型黑土区海伦市光荣小流域不同处理方式的坡耕地径流小区监测数据,采用K均值聚类法和通径分析法,系统研究了不同降雨类型事件中坡耕地产流产沙对影响因素的响应.研究结果发现,研究区以中等历时、中等雨强、中等雨量的降雨(RⅢ)为主,其次是长历时、中等雨量的变雨强类型降雨(RⅡ),长历时、大雨量、大雨强的大暴雨(RⅠ)极少发生.横坡垄作对RⅢ的水土保持防护效益明显优于RⅡ.在免耕、少耕、顺坡垄作和裸坡小区,RⅡ和RⅢ的平均次降雨径流深相差较小,但RⅢ的土壤流失量明显高于RⅡ,RⅢ是研究区土壤流失的主要贡献者.降雨量和降雨侵蚀力分别在RⅢ和RⅡ中对产流具有较大影响.水土保持措施通过直接和间接影响径流深的作用进而控制土壤流失量.作物经营管理对土壤流失量的影响以间接效应为主.本文研究结果表明不同处理小区的径流深和土壤流失量均具有显著差异,实施水土保持措施能明显减少产流产沙.单纯从防治水土流失的角度考虑,横坡垄作是该区最为适宜的水土保持措施,其次是免耕,不推荐少耕措施.     

科尔沁沙地降雨特征分析——以奈曼旗为例北大核心CSCD

了解降水的当前特征及未来的变化趋势对理解气候变化对区域生态系统的影响具有重要的意义。科尔沁沙地是中国北方农牧交错带的典型区域,年降雨量300~500mm,对气候变化（特别是降水的变化）非常敏感。对科尔沁沙地沙漠化较为严重的奈曼旗1971—2013年的降水资料进行了分析研究。结果表明：（1）该地区多年平均降水量为338.8mm,5—9月降雨量占全年降水量的（85.32±7.71）%,5—9月降雨量、年降水量1971—2000年经历了先增加后减少的趋势,2001—2013年有缓慢增加的趋势;同时降水量的年际变异性近10年也呈增加的趋势。（2）5—9月降雨量呈先增大后减小的趋势,在7月最大,为104.2 mm,5月和9月最小（分别为32.7 mm和32.8mm）,月降雨量的年际变率均大于49%;生长季内降雨主要以〈10mm的事件为主,占总降雨事件的64.41%,却仅占总降雨量的16.95%;≥30mm的降雨事件占总降雨事件的10.96%,占到总降雨量的45.93%,且对总降雨量具有决定性的影响。（3）≥5mm降雨的平均间隔为9.4d,以1~10d为主,占到69.5%,10~20d（19.5%）的次之;≥30d的发生频率最小,为3.81%,降雨间隔的年际变异性均呈增加的趋势。（4）生长季降雨日数呈减少的趋势,降雨事件降雨量的变异性与生长季降雨量的变化具有相似性,从2001年开始呈增加的趋势。该地区的降雨量年际变异性强,降雨日数的减少和降雨事件降雨量变异性的增加将提高极端干旱事件发生的频率,可能对该地区的生态系统产生严重影响,加剧该地区的沙漠化发展方向。因此,加强气候变化对生态系统影响的研究,可为合理利用土地资源及调整土地管理方式提供理论依据。     

福州市降雨量及降雨侵蚀力变化趋势

根据福州市年降雨量数据资料,采用变异系数、趋势系数和气候趋势率等方法分析不同时间尺度的降雨和降雨侵蚀力的变化趋势。结果表明:(1)福州市年平均降雨侵蚀力和降雨量分别为393.06 MJ·mm·hm~(-2)·h~(-1)和1 394.43 mm。降雨侵蚀力和降雨总量年际波动显著,且年降雨量和降雨侵蚀力年内变化较大,主要集中在5、6、8、9月。(2)总体上夏季、秋季和冬季降雨侵蚀力的倾向率为正,分别为7.57、0.39和1.40 MJ·mm·hm~(-2)·h~(-1)·10 a~(-1),春季降雨侵蚀力倾向率为负值,呈减少趋势。(3)月降雨量和降雨侵蚀力的变化趋势基本一致,1、2、4、7、8、10、11、12月降雨侵蚀力有增加的趋势,3、5、6、9月降雨侵蚀力有减少的趋势。(4)福州雨季的降雨量和降雨侵蚀力分别为990.61 mm和285.90MJ·mm·hm~(-2)·h~(-1),并且其变异系数在全年中最小,均低于0.22;枯季的降雨量和降雨侵蚀力分别为403.82 mm和107.16MJ·mm·hm~(-2)·h~(-1),变异系数在全年中最大,均高于0.40,且福州降雨量和降雨侵蚀力在雨季、枯季及其年际变化均属于中等变异性(0.1≤CV≤1)。研究结果可为福州市的土壤侵蚀评估、预报和水土流失防治提供数据和理论支撑。     

黄土丘陵沟壑区坡面土壤侵蚀的临界坡度

坡度是重要的地貌因子.采用岔巴沟径流场和王家沟径流场资料,首先研究坡度与最大30 min雨强(I30)对土壤侵蚀影响,然后确定了主导侵蚀为溅蚀片蚀与主导侵蚀为细沟侵蚀之间的临界雨强,最后探讨了不同侵蚀类型下的临界坡度.结果表明:1.坡度与降雨强度存在明显的交互作用,随着坡度的增大,雨强对土壤侵蚀的影响增大;2.团山沟的溅蚀片蚀与细沟之间的临界I30为0.31 mm/min,同时,该临界雨强不是一定值,受下垫面因素等影响而具有一定的波动范围;3.以溅蚀片蚀为主时,土壤侵蚀存在一个＜31°的临界坡度,侵蚀模数随坡度的变化趋势与径流模数随坡度变化的趋势相同,从9°～31°土壤侵蚀模数随坡度增加是先增加后减小;以细沟侵蚀为主时,在9°～31°间土壤侵蚀不存在临界坡度,土壤侵蚀模数随坡度的变化趋势与径流含沙量随坡度变化的趋势相同,从9°～31°土壤侵蚀模数随坡度增加先逐渐增加后缓慢增加,临界坡度＞31°.     

陕西省降雨侵蚀力时空分布特征

根据陕西省全省96个数据序列较完整的气象站点逐日降水资料,利用章文波提出的基于日降雨侵蚀力模型估算陕西省的降雨侵蚀力,并采用反距离权重空间插值方法,借助GIS工具绘制全省侵蚀性降雨量以及侵蚀性降雨量空间分布图,分析其全年和四季空间分布特征,并分析了年内变化特征。结果表明:(1)陕西省降雨侵蚀力的空间分布与侵蚀性降雨量的空间分布基本一致,均呈由南向西北递减态势,降雨侵蚀力与降雨量、侵蚀性降雨量均达极显著相关水平;(2)降雨侵蚀力年内集中度高,夏秋季降雨侵蚀力较大,冬春季降雨侵蚀力较小,陕北地区和关中发生水土流失的时期主要集中在7~9月份,而陕南地区5~10月份均可能发生较大的水土流失,侵蚀潜在危险性由北向南递增;(3)陕西省降雨侵蚀力的年际变化也较为明显,年际变率CV在33.1%~77.3%,不同地区的年降雨侵蚀力差异及波动程度都比较大,北部地区降雨侵蚀力的年际变化大于南部地区。     

不同森林经营方式下幼林地水土流失对降雨增强的响应

研究自然降雨梯度下不同经营方式森林的径流和泥沙量有助于预测未来气候变化背景下水土流失模式。选择次生林以及由其转换而来的米槠人工幼林(人工幼林)和人工促进天然更新幼林(人促幼林)为研究对象,选取47场自然降雨事件构成一个降雨梯度,探讨不同森林类型水土流失对降雨增强的响应差异及其内在机制。结果发现:人促幼林和次生林因其植被垂直结构发育,降雨侵蚀力施加的侵蚀动能被植物体抵消,水土流失量低,其产量主要受到降雨量的调控,且随降雨的加强而缓慢增加;人工幼林覆盖度低,林下裸露,水土流失受到降雨侵蚀力的直接影响,产流和输沙量大,而且随着降雨强度的增加而快速增加.未来应多提倡人工促进更新的方式,人工林的经营要加强林下管理,增加覆盖。     

AN EXPERIMENTAL STUDY OF SHEET EROSION IN GRANITIC REGION OF WUHUA COUNTY,GUANGDONG PROVINCE

1.IntroductionWuhuaCounty,locatedintheupstreamOfHanjianghiver,isoneofthemostseriouslyerodedcountiesinSouthChinagraniticweatheringregionOfGUangdOngPrOvince.ByinveStighion,thetOtalerodedareaisestimatedtobe875.33km,whichoccupiedbot30percentofthetOtalerodedareaoftenmostseriouserodedcountiesintheregion.Insomeconununes,theeroddareaevenreachedtomorethan6Opercent.ErosionresuItedinwidesPedOfbemountalns,landdopadaion,shortOfwterresourceshoperecotw.~ngthethreetypesoferosionintheupstreamOfHanjian…     

Erosion rates in badland areas recorded by collectors,erosion pins and profilometer techniques (Ebro Basin,NE-Spain)

In badland areas of the Ebro Basin, in a semiarid climate, two erosion plots (257 m²; 5° slope and 128 m²; 23° slope) on exposed Tertiary clays were monitored over two years (Nov. 1991–Nov. 1993). This material is characterized by high sodium absorption ratios which lead to high soil dispersivity. The dominant erosion processes in both plots are rilling and sheet erosion. Rainfall intensity was recorded at a weather station, connected to a data-logger, sediment production for single events was collected in tanks, and ground lowering was measured every six months by erosion pins and microtopographic profile gauge techniques. Significant runoff was produced only by rainfall events above 5 mm. Another threshold at 20 mm rain was noted. For rainfalls higher than 20 mm, the 23° slope plot shows a greater runoff response than the 5° one. Rainfall events exceeding this threshold showed a higher sediment production for the steeper slope. In the relationship between precipitation and sediment concentration, an envelope curve can be drawn indicating that any rainfall event of a given amount and intensity has a maximum sediment concentration which we speculate to be a function of the runoff sediment transport capacity. Runoff response and sediment yield in the studied plots are controlled by the rainfall and soil characteristics and their seasonal variations. In both plots, the erosion pins show that erosion rates in rill areas are 25–50% higher than in the interrill areas. Sediment yield recorded by collector devices was higher than the rates measured by erosion pins. The erosion rates based on rill cross-sections by profilometers were higher than the ones recorded by collectors.     

Intra-event characteristics of extreme erosive rainfall on Mauritius

Mauritius is a volcanic island with a raised interior where extreme rainfall events dominate rainfall erosivity. Intra-event characteristics of the 120 highest erosive events at six selected locations between 2004 and 2008 were analyzed to provide the first detailed intra-storm data for a tropical island environment. On Mauritius, spatial variation is evident in the characteristics of extreme erosive rainfall recorded at the stations, with a noticeable increase in rainfall depth, duration, kinetic energy, and erosivity of extreme events with altitude. Extreme events in the raised interior (central plateau) show high variability of peak intensity over time as well as a higher percentage of events in which the greatest intensity occurs in the latter part of the event. Intra-event distribution of rainfall in the interior of the island shows that rainfall there has a higher potential to exceed infiltration rates as well as the ability to generate high peak runoff rates and cause substantial soil loss. The study suggests that even though within-event rainfall characteristics are complex, they have implications for soil erosion risk, and that, in tropical island environments, the within-storm distribution of rainfall should be incorporated in soil-loss modeling.     

Relations between interrill erosion processes and sediment particle size distribution in a semiarid Mediterranean area of SE of Spain

Erosion and sediment characteristics were measured using simulated rainfall on two cultivated soils of contrasting lithology (Quaternary calcareous colluvium and Tertiary marls) in a semiarid Mediterranean area of SE Spain. Two rainfall intensities, high (56.0±2.4 mm h⁻¹) and medium (31.4±1.4 mm h⁻¹), were used in order to know the mechanisms involved in each selected condition. For each simulated event, runoff and sediment were sampled at 1-min intervals on a 1-m wide by 2-m long erosion plot. The erosion rate was calculated as the total amount of soil lost divided by the time period of the test. The duration of the test was that needed to reach steady state runoff, an average time of 24.5 min for Quaternary calcareous colluvium and 17.7 min for Tertiary marls. The size distribution of the transported sediment in the field (effective size distribution) was compared with equivalent measurements of the same samples after chemical and mechanical dispersion (ultimate size distribution) to investigate the detachment and transport mechanisms involved in sediment mobilisation. The results showed that the soil type determined the hydrological response, regardless of the rainfall intensity. The erosional response was, however, determined by the rainfall and soil surface characteristics.In Quaternary calcareous colluvial soils, the predominant erosion process depended on the rainfall intensity, with a prevailing detachment-limited condition in high-intensity events and prevailing transport-limited conditions in those events of medium intensity. These differences in the main erosion processes were reflected in the size of the transported material and in the change in sediment size within the storm. Thus, a time-dependent size distribution of the eroded material (decreasing coarse fractions and increasing fine fractions with runoff time) was observed for high-intensity events. In medium-intensity events, on the other hand, the time-independent size distribution of the eroded material indicated transport-limited erosion.Due to the rapid surface crusting on the Tertiary marl soil, no differences in the main erosion processes or in the sediment size distribution occurred for the different rainfall intensities tested. The erosion of marl soils was determined mainly by the limited quantity of available sediment.The effective size of material was a more sensitive parameter than the ultimate size of the sediment to study the way in which the sediment was transported.     

沙层特性对沙盖黄土坡面产流产沙变化贡献的定量分析

沙盖黄土坡面产流产沙方式独特,侵蚀过程复杂,量化降雨过程中该类坡面产流产沙变化影响因素贡献的大小对揭示其侵蚀机理具有重要的意义。基于室内模拟降雨试验,定量分析沙层厚度（2 cm、5 cm和10 cm）和粒径组成（100%粒径≤ 0.25 mm、75%粒径≤ 0.25 mm +25%粒径> 0.25 mm、50%粒径≤ 0.25 mm+50%粒径> 0.25 mm、未处理原沙和100%粒径> 0.25 mm）在降雨过程中对产流产沙变化的影响和贡献。结果显示：沙层厚度增加能明显延长产流时间,减少总产流量,增加总产沙量,增大降雨过程中产流产沙的变异性;随沙层粒径组成变粗,初始产流时间和产沙量无明显变化规律,产流量有增大趋势。沙层厚度、粒径组成及二者交互作用对初始产流时间变化的贡献率分别为68.03%、15.77%和3.85%。沙层厚度对降雨不同时段15 min产流量和不同历时总产流量的贡献率分别在23.89%~52.22%和41.10%~48.94%之间,对相应产沙的贡献率分别在29.19%~62.01%和13.53%~30.31%之间。整体上沙层粒径组成变化对产流产沙量变化的贡献率小于沙层厚度,且无明显规律。沙层厚度和粒径组成交互作用对产流量和降雨中前期产沙量的影响显著（p < 0.05）,其对产流产沙变化的贡献率分别在13.12%~26.62%和3.22%~43.12%之间,不同降雨时段变化明显。研究结果说明,沙层厚度决定沙盖黄土坡面产流产沙过程,其和沙层粒径组成对产流产沙的影响和贡献随坡面沙层的侵蚀演化而动态变化,且二者的交互作用也不容忽视。     

Slope runoff study in situ using rainfall simulator in mountainous area of North China

Simulated rainfall is a valid tool to examine the runoff generation on the slope.13 simulated rainfall experiments with different rainfall intensities and durations are completed in a 5 m ×10 m experimental plot in mountainous area of North China.Simultaneously,rainfall,surface runoff,soil-layer flow,mantel-layer flow and soil moisture are monitored respectively.From the results,it is found that the hydrographs in all layers have the characteristics of rapid rise and fall.The recessions of surface flow and soil-layer flow are much faster than that of mantel-layer flow.Surface flow,the main contributor,makes up more than 60% of the total runoff in the study area.It even exceeds 90% in the cases of high intensity rainfall events.Runoff coefficient(ratio of total runoff to rainfall amount) is mainly influenced by rainfall amount,rainfall intensity and antecedent soil moisture,and the relationship can be well expressed by a multiple linear regression function α = 0.002P + 0.182i + 4.88Wa-0.821.The relation between the rainfall intensity and the lag time of three flows(surface runoff,soil-layer flow and mantel-layer flow) is shown to be exponential.Then,the result also shows that the recession constant is 0.75 for surface runoff,is 0.94 for soil-layer and mantel-layer flow in this area.In this study area,the dominant infiltration excess runoff is simulated by Horton model.About 0.10 mm/min percolation is observed under the condition of different rainfall intensities,therefore the value is regarded as the steady infiltration rate of the study area.     

华北山区坡地产流规律研究

Simulated rainfall is a valid tool to examine the runoff generation on the slope. 13 simulated rainfall experiments with different rainfall intensities and durations are completed in a 5 m ×10 m experimental plot in mountainous area of North China. Simultaneously, rainfall, surface runoff, soil-layer flow, mantel-layer flow and soil moisture are monitored respectively. From the results, it is found that the hydrographs in all layers have the characteristics of rapid rise and fall. The recessions of surface flow and soil-layer flow are much faster than that of mantel-layer flow. Surface flow, the main contributor, makes up more than 60% of the total runoff in the study area. It even exceeds 90% in the cases of high intensity rainfall events. Runoff coefficient (ratio of total runoff to rainfall amount) is mainly influenced by rainfall amount, rainfall intensity and antecedent soil moisture, and the relationship can be well ex-pressed by a multiple linear regression function a = 0.002P + 0.1821 + 4.88Wa - 0.821. The relation between the rainfall intensity and the lag time of three flows (surface runoff, soil-layer flow and mantel-layer flow) is shown to be exponential. Then, the result also shows that the recession constant is 0.75 for surface runoff, is 0.94 for soil-layer and mantel-layer flow in this area. In this study area, the dominant infiltration excess runoff is simulated by Horton model. About 0.10 mm/min percolation is observed under the condition of different rainfall intensities, therefore the value is regarded as the steady infiltration rate of the study area.     

IMPACTS OF DIFFERENT TYPES OF LAND USE ON PROCESSES OF SOIL AND WATER LOSS OVER PURPLE SOIL SLOPELAND

ＳｌｏｐｅｌａｎｄａｍｅｌｉｏｒａｔｉｏｎａｎｄｕｔｉｌｉｚａｔｉｏｎｗｉｔｈｃｏｍｐｌｅｘａｇｒｏｆｏｒｅｓｔｒｙｓｙｓｔｅｍｒａｉｓｅｄｂｙＰｒｏｆｅｓｓｏｒＨｕａｎｇＢｉｎｇｗｅｉｗａｓｍａｉｎｌｙａｉｍｅｄａｔｉｍｐｒｏｖｉｎｇｓｌｏｐｅｌａｎｄｓｕｓｔａｉｎａｂｌｅｐｒｏｄｕｃｔｉｖｉｔｙｂｙｕｓｉｎｇｂｉｏｌｏｇｉｃａｌｍｅａｓｕｒｅｓｆｏｒｔｈｅｐｕｒｐｏｓｅｏｆｐｒｏｖｉｄｉｎｇｎｅｗｍｅｔｈｏｄｆｏｒｆｕｔｕｒｅｃｏｍｐｒｅｈｅｎｓｉｖｅｅｘｐｌｏｉｔａｔｉｏｎａｎｄｕｔｉｌｉ…     

黄土坡面发育平稳的细沟流水动力学特性

由于天然降雨存在间歇性,常会出现前期降雨已经发育成型的细沟又经历了二次降雨的情况,但目前对这一条件下细沟流水动力学特性的研究还很少。本文采用室内人工模拟降雨的方法,通过间隔24 h两场不同雨强的降雨,研究黄土坡面经过第一场降雨形成比较稳定的细沟之后,在第二场较小雨强降雨过程中,细沟发育平稳时的流水动力学特性。研究结果表明:①细沟流速大小受坡长影响并不显著,相同坡度下不同坡长的细沟流平均流速差别不大;细沟流速受细沟形态影响较大,25°坡面比20°坡面细沟密度大,流速相对较小;②剪切力大小受流量和坡度共同作用;雷诺数与水流剪切力呈显著正相关关系,弗洛德数与水流剪切力则呈显著负相关关系;③随着距坡顶距离的增加,阻力系数呈增大趋势;第二次降雨强度相同,坡度大的坡面上阻力系数也较大,可见阻力系数与径流量和坡度的关系十分紧密;阻力系数与雷诺数之间呈显著正相关关系,雷诺数的增加意味着平均流速增大,水流强度增大导致细沟形态更为复杂,水流受到的阻力增大;虽然雷诺数增加同时也意味着水流深度增大,但从试验结果可见,陡坡条件下阻力系数受流速的影响较大。     

坡地土壤氮素与降雨、径流的相互作用机理及模型

坡地土壤氮素径流损失表现为两种形式 ,溶解于径流中的矿质氮随径流液流失 ,吸附于泥沙颗粒表面以无机态和以有机质形式存在的氮素。坡地土壤氮素流失过程实际上是表层土壤氮素与降雨、径流相互作用的过程 ,土壤氮素流失的多少主要受相互作用的限制。从分析土壤与降雨、径流相互作用入手 ,分析了土壤氮素与降雨、径流相互作用过程及机理 ,并对相互作用模型进行探讨。