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1.
作物残茬对农田土壤风蚀的影响   总被引:32,自引:4,他引:28  
通过对不同留茬高度对地表风速的影响以及留残茬(保护性耕作主要方式)、旋耕和常规翻耕3种耕作方式对土壤风蚀的影响进行比较研究,得出如下结果:留茬高度对地表风速的影响程度不明显,仅与地面有无留茬有关,留茬20cm左右即可有效降低地表风速,减少田间扬沙,抵抗土壤风蚀,是比较适宜的留茬高度;留茬(保护性耕作)、旋耕和常规翻耕3种耕作方式对田间扬沙情况的影响差异明显,其中在60cm高度以内,留茬比常规翻耕减少田间扬沙量34.9%,比旋耕方式减少61.5%,因此,留茬(保护性耕作)是一种有效防止农田土壤风蚀的耕作方式。  相似文献   

2.
为研究河西绿洲灌区保护性耕作对土壤风蚀的影响,通过春小麦田间试验,设置免耕不覆盖、免耕秸秆覆盖、立茬和残茬压倒4种保护性耕作处理,以传统耕作为对照,分析了河西绿洲灌区不同保护性耕作措施对田间输沙量、风蚀深度、风蚀物粒径组成、风速的影响。结果表明:0~30 cm高度输沙量能敏感地反映不同耕作措施之间输沙量的差异。与传统耕作相比,免耕不覆盖、免耕秸秆覆盖、立茬和残茬压倒处理0~30 cm高度输沙量分别减少17.4%~46.7%、21.7%~45.2%、24.7%~48.2%和10.7%~42.4%。风蚀深度传统耕作为1.22~1.44 mm,4种保护性耕作处理均为0 mm。与传统耕作相比,保护性耕作处理风蚀物粒径组成无显著变化,但<0.063 mm细粒占比有减小趋势。立茬处理20 cm高度风速显著降低24.1%~39.5%,其他保护性耕作措施风速降低不显著。综上所述,河西绿洲灌区不同保护性耕作措施能不同程度地抑制土壤风蚀,立茬处理是相对较优的保护性耕作措施,适宜该地区推广应用。  相似文献   

3.
针对内蒙古阴山北麓农牧交错带土壤风蚀严重的问题,研究了带状留茬间作的防风蚀效果,通过测定风速、地表粗糙度和土壤风蚀量,揭示不同留茬高度对留茬地和相邻裸露地的防风蚀效果.结果表明,随着留茬高度的增加,作物残茬带近地表风速降低,且留高茬(30 cm)效果最明显;随着测定高度的增加,同一留茬高度对风速的降低程度减小.地表粗糙度随留茬高度的增加而增大,留高茬地(30 cm)和邻高茬裸地的地表粗糙度分别较对照增加了466.67%和126.98%.土壤风蚀量随留茬高度的增加而减少,留高茬地(30 cm)和邻高茬裸地的风蚀量分别较对照减少了90.21%和65.51%.因此,作物残茬既增强了自身带的防风蚀效果,又在一定程度上保护了邻茬裸露带,留茬高度30 cm时防风蚀效果最好,对相邻裸露带的保护作用最明显.  相似文献   

4.
河西绿洲灌区保护性耕作防风蚀效应的风洞试验研究   总被引:2,自引:0,他引:2  
通过对河西地区民勤县绿洲春小麦生产田实施保护性耕作,采用风洞试验,以传统耕作为对照,从风蚀量、风速廓线、风蚀速率和地表粗糙度等方面比较分析了不同保护性耕作措施(免耕不覆盖、免耕秸秆覆盖、残茬压倒处理)的防风蚀效应。结果表明:与传统耕作相比,保护性耕作土壤风蚀量减少,地表风速减小,土壤风蚀速率降低,地表粗糙度增大,土壤风蚀速率与地表粗糙度呈负相关关系。不同保护性耕作措施抑制风蚀的程度不同,4种耕作方式的风蚀速率从大到小依次为传统耕作、残茬压倒、免耕不覆盖、免耕秸秆覆盖,其中免耕秸秆覆盖处理的防风蚀效应最佳。  相似文献   

5.
保护性措施对农田土壤风蚀影响的室内风洞模拟   总被引:3,自引:0,他引:3  
为寻求合理的保护性耕作措施,试验设计了砾石覆盖、秸秆覆盖、覆盖与留茬组合的措施和4个风速等变量,研究风速、覆盖物和覆盖度与风蚀量、抗风蚀效率、风沙流结构的关系,比较多种措施之间的抗风蚀效果优劣.结果表明:1)4个设定风速下30% ~ 90%覆盖度的秸秆覆盖的抗风蚀效率在54% ~ 92%之间,砾石覆盖为26%~72%,30%的砾石覆盖或30%的秸秆覆盖与3种留茬高度的组合措施下,平均抗风蚀效率均在70% ~ 78%之间;2)随着覆盖度的增加,砾石覆盖措施最小可抑制的有效风速值从8.0 m/s逐渐增大到12.5 m/s,秸秆覆盖措施从10.1m/s增加到了14.3 m/s;3)覆盖处理下0~62 cm高度内的输沙量大部分集中在0~26 cm;4)覆盖与留茬组合措施的输沙量多集中在60 cm以内.  相似文献   

6.
地表覆被因子对华北寒旱区土壤抗风蚀力的影响   总被引:1,自引:0,他引:1  
为了明晰不同类型土壤的抗风蚀力特征与华北寒旱区农田地表覆被因子减降土壤风蚀的效果,采用国家发明专利"土壤风蚀测定装置",通过室内模拟与田间实证研究,分析砂砾、垡片覆被以及耕作措施、残茬存留等地表覆被因子对不同类型农田土壤抗风蚀力的影响。结果表明,砂质栗钙土抗风蚀能力高于壤质草甸栗钙土,在连续吹蚀下地表土壤吹蚀量呈"L"形下降特征;砂砾与垡片覆被可显著增强土壤抗风蚀能力,随覆被度增加土壤吹蚀量呈近线性指数型下降特征。华北寒旱区多年免耕的燕麦留茬农田,地表土壤吹蚀量较传统翻耕田降低70.28%~88.42%,多年免耕的地表砂砾覆被对增强砂质栗钙土农田的抗风蚀力起重要作用;而留茬覆被的粗糙度效应对增强壤质草甸栗钙土农田抗风蚀力更为重要。壤质草甸栗钙土秋耕立垡覆被,较传统翻耕田地表土壤吹蚀量降低92.21%。研究表明,生物性残茬覆被、非生物性砂砾与垡片覆被具有显著提高土壤抗风蚀力效应;在华北寒旱区农田,燕麦留茬免耕覆被可显著降低土壤吹蚀量;对无植被存留条件的壤质草甸栗钙土农田,秋耕立垡覆被同样具有显著提高土壤抗风蚀力效果。  相似文献   

7.
农田休闲期作物留茬对近地表风场的影响   总被引:5,自引:0,他引:5  
茬是防治农田休闲期土壤风蚀的有效措施。该文利用野外观测数据,通过比较不同高度的4种作物留茬及冰草覆盖地表的风速廓线,分析各种处理下近地面风速和空气动力学特征,揭示作物留茬防止土壤风蚀的机制。结果表明:作物留茬降低了地面以上2 m高度内的风速,降低幅度与留茬高度成正比,与观测高度成反比。高度相同时不同类型的留茬比较,莜麦和小麦茬下风速降低幅度较大,植株稀疏的油菜茬和秸秆较细的胡麻茬的防风效果较差。同类作物不同高度的留茬覆盖下,地表空气动力学粗糙度随留茬高度的增加而增大,在莜麦、油菜和小麦茬高度达到15、30和15 cm时显著增大,是3种留茬防风的有效高度。可见,高度适宜的作物留茬能降低近地面风速,削弱侵蚀力,有效防治土壤风蚀。  相似文献   

8.
保护性耕作对农田土壤风蚀影响的室内风洞实验研究   总被引:1,自引:0,他引:1  
保护性耕作能够有效减少农田土壤风蚀。通过室内风洞实验,定量分析不同作物留茬、不同秸秆覆盖量对安塞黄绵土风蚀作用的影响。结果表明:(1)小麦留茬、玉米留茬以及秸秆覆盖都可以有效的减少风蚀。小麦秸秆覆盖量为4 210kg/hm2时土壤抗风蚀效率最高,达到95.9%;(2)风蚀量与风速成正相关关系,风蚀量随风速的变化均存在突然增大的转折点且30cm小麦留茬的转折点会明显滞后于30cm玉米留茬和裸土,30cm小麦留茬的抗风蚀效率要好于30cm玉米留茬;小麦秸秆覆盖量越大,抗风蚀效率越好;(3)随着高度的增加风蚀量逐渐减小,超过90%的风蚀量都集中在0~36cm高度范围内。随着风速的增大,0~10cm风蚀量所占比例会逐渐增加。  相似文献   

9.
高寒地区不同土地利用方式对土壤抗风蚀能力的影响   总被引:1,自引:0,他引:1  
采用风洞实验对祁连山东段天祝高寒地区天然放牧草地、退耕自然恢复草地、翻耕地、免耕留茬地和人工种植多年生草地5种土地利用方式下的原状土抗风蚀能力进行了研究。结果表明,多年生草地的临界侵蚀风速最大,免耕留茬地和天然草地次之,翻耕地和退耕自然恢复地最小;风蚀速率与风速变化成正相关,随着风速增大,风蚀速率相应增加;风蚀速率和风速变化服从幂函数变化关系。在近地表0-20cm范围内,降尘量总量依次为退耕自然恢复地翻耕地天然放牧草地多年生草地免耕留茬地;土壤抗风蚀能力表现为退耕自然恢复地天然放牧草地多年生草地免耕留茬地翻耕地。  相似文献   

10.
土壤风蚀是指松散的土壤物质被风吹起、搬运和堆积的过程以及地表物质受到风吹起的颗粒的磨蚀过程,其实质是在风力的作用下,表层土壤中的细颗粒和营养物质的吹蚀、搬运与沉积的过程。我国受土壤风蚀及土地沙漠化影响的面积占国土总面积的1/2以上,主要分布于北方干旱、半干旱地区。甘肃河西走廊是我国荒漠化最严重的地带之一,该地区春小麦种植长期采用铧式犁翻耕是导致该地区农田土壤风蚀的主要原因。通过室内风洞试验揭示了冬小麦保护性耕作措施条件下风蚀量、起动风速、风速廓线、地表粗糙度的差异及相关关系。结果表明,各个处理风蚀量、起动风速均高于对照处理,风蚀量与风速存在幂函数关系,16 m s-1风速是土壤风蚀程度由轻变重的一个转折点;在距土样表面5~50 mm范围内,随着高度的递增免耕秸秆覆盖(NTS)、免耕不覆盖(NT)处理较秸秆翻压(TIS)、传统耕作(T)处理风速增加缓慢,每个处理高度(H)与风速(V)遵循指数函数。NT、NTS处理与对照(SWT)的粗糙度K的差异在0.01水平上达到了极显著,TIS处理与对照(SWT)在0.05水平上差异显著,而T处理与对照(SWT)差异不显著。风蚀率(Q)与地表粗糙度(K)之间存在显著负相关关系。起动风速与地表粗糙度存在显著负相关关系。  相似文献   

11.
徐涛  蒙仲举  党晓宏  包斯琴 《土壤》2018,50(3):606-612
土壤风蚀是干旱地区绿洲农田开发的一个突出生态问题,如何针对不同的立地单元采取保护性措施是人们长久以来关注的重点。本文选择乌兰布和沙漠绿洲农田流沙地、沙质耕地、黏质耕地、撂荒耕地及留茬地5种典型土地利用方式,对其风速特征、地表蚀积量进行野外原位测定,并分析了不同下垫面的地表粗糙度和沉积土壤粒径特征。结果表明:研究区土壤颗粒组成以细砂含量占主导地位,粉粒、中砂与粗砂含量相对较低。与对照相比,各土地利用方式均能有效增加地表粗糙度,表现为:留茬地(0.32 cm)撂荒耕地(0.29 cm)沙质耕地(0.25 cm)黏质耕地(0.19cm)流沙地(0.02 cm)。土壤风蚀深度整体表现为流沙地沙质耕地撂荒耕地黏质耕地留茬地,5种利用方式下,留茬地风蚀程度最轻,风蚀深度仅为0.04 cm/d,分别较流沙地、沙质耕地、黏质耕地及撂荒耕地降低了99.03%、96.83%、94.29%与90.24%。因而,留茬地具有较好的防风蚀效益,是一种值得推广的土壤风蚀防治措施。  相似文献   

12.
In the semiarid region of northwest China, pebble mulches have been used by farmers for over 300 years. However, very little studies were conducted on the effect of pebble mulch on soil erosion by wind. Results of a wind tunnel simulation and a field experiment showed that pebble mulch had two functions in controlling wind erosion: first, it could prevent soil from eroding by wind; second, it could trap dust carried by wind. According to the wind tunnel simulation experiment, pebble mulch reduced wind erosion rate (g m−2 min−1) by 84–96% at the different wind velocities (10–26 m s−1) in comparison with the controls. In addition, the ratio between total soil loss from the pebble-mulched soil and the bare soil was 0.06. The field study indicated that pebble mulch could trap 1.6–1.8 times more windblown sediments than the control suggesting that pebble mulch might also be effective in controlling dust storms. The grain size distribution of eroded soil showed that a lower percentage of particles in the range of >1.0 mm fractions and a higher percentage in the range of <0.05 mm fractions occurred in the pebble-mulched treatments than in the controls, while windblown sediments trapped by pebble mulches had a lower percentage of grains in the range of >0.5 and <0.05 mm fractions than that trapped by the controls.  相似文献   

13.
Spatial modeling of wind speed around windbreaks   总被引:3,自引:0,他引:3  
This paper presents a model to integrate windbreak shelter effects into a Geographic Information System (GIS). The GIS procedure incorporates the 1999 version windbreak sub-model of the Wind Erosion Prediction System (WEPS). Windbreak shelter is modeled in terms of friction velocity reduction, which is a function of wind speed and direction, distance from the barrier, windbreak height, porosity, width, and orientation. A first application of the model was conducted at a study area with an extensive windbreak network in England (Thetford, East Anglia). Windbreak characteristics (windbreak type, height, width, porosity, and location) were recorded. Porosity was estimated from digitized B/W silhouettes. To evaluate the network effectiveness, a windbreak network shelter index (SI) was proposed in terms of average reduction of friction velocity over the area due to network shelter. The network was found to give good protection, but the windbreak distribution was not optimal in relation to the wind vector distribution.  相似文献   

14.
杨秀春  严平  刘连友  徐斌 《土壤学报》2005,42(5):737-743
在农牧交错带——内蒙古自治区太仆寺旗采集的土壤样品的风洞实验研究结果表明:耕作模式的不同导致土壤风蚀状况的差异。在深松、翻耕、翻耕碾碎、小麦茬10 cm、荞麦茬10 cm、胡麻茬10 cm与无残茬等7种耕作模式的风洞实验中,翻耕碾碎风蚀速率均值最大,达到124.8 g m-2 min-1,胡麻茬最小,为15.14 g m-2 min-1,前者是后者风蚀速率的8.24倍。7种耕作模式风蚀速率均值的大小顺序为:翻耕碾碎>无残茬>深松>荞麦茬>翻耕>小麦茬>胡麻茬。结合对不同耕作模式土壤风蚀速率与风速关系的进一步分析可定量揭示出:翻耕碾碎、无残茬模式防风蚀效果最差,胡麻茬、小麦茬、翻耕模式防风蚀效果最好,深松、荞麦茬防风蚀效果居中。本文结论对农牧交错带旱作农业增强农田防风抗蚀能力有借鉴意义。  相似文献   

15.
Soil properties and surface characteristics affecting wind erosion can be manipulated through tillage and crop residue management. Little information exists, however, that describes the impact of long term tillage and residue management on soil properties in the subarctic region of the United States. This study examines the impact of 20 years of tillage and residue management on a broad range of physical properties that govern wind erosion processes on a silt loam in interior Alaska. A strip plot experimental design was established in 1983 and included intensive tillage (autumn and spring disk), spring disk, autumn chisel plow, and no tillage with straw either retained on or removed from the soil surface. Soil and residue properties measured after sowing barley (Hordeum vulgare L.) in May 2004 included penetration resistance, soil water content, shear stress, bulk density, random roughness, aggregate size distribution, and residue cover and biomass. No tillage was characterized by larger aggregates, greater soil strength (penetration resistance and shear stress), wetter soil, and greater residue cover compared to all other tillage treatments. Despite crop failures the previous 2 years, crop residue management influenced residue biomass and cover, but not soil properties. Autumn chisel and spring disk appeared to be viable minimum tillage options to intensive tillage in controlling erosion. Autumn chisel and spring disk promoted greater roughness, aggregation, and residue cover as compared with intensive tillage. Although no tillage appeared to be the most effective management strategy for mitigating wind erosion, no tillage was not a sustainable practice due to lack of weed control. No tillage also resulted in the formation of an organic layer on the soil surface over the past 20 years, which has important ramifications for long term crop production in the subarctic where the mean annual temperature is <0 °C.  相似文献   

16.
Within the European Union (EU)-funded Project ‘Wind Erosion on European Light Soils’ (WEELS), a model was designed and implemented with the aim of predicting the long-term spatial distribution of wind erosion risks in terms of erosion hours and wind-induced soil loss. In order to ensure wide applicability, the model structure consists of a modular combination of different approaches and algorithms, running on available or easily collected topographic and climatological data input. Whereas the ‘WIND’, ‘WIND EROSIVITY’ and ‘SOIL MOISTURE’ modules combine factors that contribute to the temporal variations of climatic erosivity, the ‘SOIL ERODIBILITY’, ‘SURFACE ROUGHNESS’ and ‘LAND USE’ modules predict the temporal soil and vegetation cover variables that control soil erodibility. Preliminary simulations over a 29-year period for the Barnham site (UK) (1970–1998) and a 13-year period for the Grönheim site (Germany) (1981–1993) generally resulted in a higher erosion risk for the English test site, where the total mean soil loss was estimated at 1.56 t ha−1 year−1 and mean maximum soil loss at about 15.5 t ha−1 year−1. The highest rates exceeded 3 t ha−1 in March, September and November. On the northern German test site, the total mean soil loss was 0.43 t ha−1 year−1. The highest erosion rates were predicted in April when they can exceed 2.5 t ha−1. The total mean maximum soil loss at this site of about 10.0 t ha−1 year−1 corresponds to a loss of about 0.65 mm. Predictions based on a land use scenario for the German site revealed that the erosion risk could be reduced significantly by changing land use strategies.  相似文献   

17.
Wind-splash erosion of bare peat on UK upland moorlands   总被引:1,自引:0,他引:1  
Jeff Warburton   《CATENA》2003,52(3-4):191
Peat is a common land surface material in many countries of the world and is particularly important in upland regions of the UK. Peat landscapes represent an important land use for hill farming, water management, and shooting, and are a globally scarce resource. Wind is a fundamental characteristic of upland environments in the UK and has long been recognised as a significant factor in peat erosion. This paper presents the first results of a project that aims to determine the significance of wind action in the erosion of upland peat. Wind erosion monitoring is being undertaken at Moor House in the North Pennines on a 3-ha area of relatively flat, sparsely vegetated peat. Measurements using arrays of passive horizontal mass flux gauges (fixed orientation vertical slot gauges), together with a vertical array of mass flux samplers (directional), provide estimates of sediment flux. A micrometeorological station records local wind speed (four heights), wind direction, rainfall, soil moisture, and temperature conditions. For 1999 and 2000, the annual horizontal net erosion flux is 0.46 and 0.48 t ha−1, respectively. Results of detailed monitoring over a 10-month period demonstrate that the peat sediment flux collected in windward- and leeward-oriented sediment traps on 10 separate occasions is between 3 and 12 times greater in the windward-facing traps. The concentration of peat with height decays rapidly and the majority of the peat is transported close to the ground surface. Above 0.3 m, very little peat is found. Significant horizontal fluxes of peat occur in both wet and dry periods. This is evaluated using the local micrometeorological data to try and predict sediment yields. Correlations among time-averaged friction velocity measurements, surface conditions, and sediment flux are complex. Event-based measurements, as opposed to cumulative sediment yields, are required to resolve this. These results quantify for the first time the significance of wind action in the erosion of peat in a UK upland environment.  相似文献   

18.
Soil erosion contributes to the removal and redistribution of soil organic C from cultivated fields. The soil organic C content of wind erodible and water unstable aggregates is an important factor in determining the amount of carbon loss occurring in erosion processes. The relative distribution of organic carbon among aggregate size fractions may also affect the response of soils to erosion. Soil organic C distribution is dependent on the chosen management system. The effects of no-till, till, and grassland management systems on organic C content of erodible and non-erodible aggregates were examined in six Ustolls and two Usterts of central South Dakota. Organic C contents were related to dry- and wet-sieving to represent the potential influence of wind and water erosion on C loss in the absence of vegetative cover. Loss of aggregate stability in cultivated soils was associated with organic C loss. Most structural characteristics developed under tilled systems persisted after 6–16 years of no-till. Changes in distribution of organic C due to management systems were most evident in Ustolls where cultivation resulted in net soil C losses. Soil organic C was not significantly increased by the no-tillage practices applied in this on-farm study (in Ustolls 49 Mg ha−1 in no-till versus 41 Mg ha−1 in till, for 0–0.20 m depth). Soil properties of Usterts were less affected by land use and management practices due to the high shrink swell action and self-mixing. In both soil orders the greater concentration of organic C in the wind erodible (<1 mm) dry aggregate size fraction implies a high potential for organic C loss by erosion in addition to organic C loss from mineralization after tillage. Grassland when compared to cultivated topsoil showed the largest amounts of organic carbon stored and the minimal potential for erosion loss of soil organic C.  相似文献   

19.
In the arid and semi-arid regions, ridge tillage was often used as an alternative practice for wind erosion control on the croplands without sufficient crop residues left during the fallow period. Through wind tunnel experiments, wind erosion rate and vertical mass flux profile of blown sand under the simulated conditions of ridge tillage and flat tillage were studied in 15, 10, 10, 5, 3 min exposures at the wind velocities of 8, 10, 15, 20, 24 m s−1, respectively. The results for the soil tested indicate that the mean rate of wind erosion under flat tillage was 129.89 g m−2 min−1, while that under ridge tillage were 20–60% less. Under ridge tillage with different structures, average wind erosion rate had a positive correlation with the spacing between adjacent ridges. For the same ridge height, average wind erosion rate decreased with increasing ratio between the height of ridge and the width of furrow. For the same ratio between the height of ridge and the width of furrow, average wind erosion rate increased with increasing height of ridge. Power function relationships were found between wind erosion rate and wind velocity on all the simulated tillage conditions. A wind velocity of 15 m s−1 was the critical velocity, above which wind erosion rate increased rapidly for the soil and simulated tillage conditions tested. Compared with flat tillage, ridge tillage remarkably decreased wind erosion rates when wind velocities were beyond 15 m s−1. Under ridge tillage, the total mass of sand transported at a height of 0–20 cm above soil surface (Q0–20), and the fraction of that travelling at a height of 0–4 cm (Q0–4/Q0–20), were less man mat under flat tillage. For the same ridge height, Q0–4/Q0–20 increased with increasing ratio between the height of ridge and the width of furrow. For the same ratio between the height of ridge and the width of furrow, Q0–4/Q0–20 decreased with increasing height of the ridge. Sand transport rate under flat tillage decreased with increasing height by a negative exponential function, while negative linear functions were found under ridge tillage. Thus ridge tillage decreased the rate of wind erosion and sand transportation near soil surface, reduced the loss of soil nutrient caused by wind erosion and plant damage caused by blown sand abrasion, which make it an effective agricultural technology for wind erosion control in the arid and semi-arid regions.  相似文献   

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