作物灌水量随机模拟研究

针对降雨、蒸发蒸腾量的随机性,在制定作物灌溉计划时,将降雨、蒸发蒸腾量进行随机化处理,采用基于时间序列的随机水文学方法对降雨和蒸发过程进行了模拟,将随机模拟出的降水、蒸发蒸腾结果代入水量平衡方程,从而确定灌溉时间和灌水量。经过和实测序列进行对比,模拟值和实际值拟合较好,最大误差仅为4.74%,可为科学制定作物灌溉计划提供参考。     

粉壤土条件下影响地下滴灌灌水器流量的因素分析

分别选取灌水器工作压力、土壤容重和土壤初始含水率为因素,采取混合水平均匀设计安排试验,对各因素实测数据进行相关、回归和通径分析,利用通径系数直接评价和比较各试验因素对地下滴灌灌水器流量的影响程度.结果表明:工作压力对灌水器流量的直接通径系数最大,土壤初始含水率和土壤容重通过工作压力对灌水器流量的间接通径系数次之,其它直接或间接通径系数很小,剩余通径系数较小.这说明试验所选的三个因素可反映地下滴灌灌水器水力要素之间的关系,其中地下滴灌中工作压力是决定灌水器流量的主要因素,土壤初始含水率和土壤容重通过工作压力对灌水器流量的作用不可忽略.     

黄土坡地径流收集膜下自流出滴灌溉系统设计及其生态效益研究

黄土坡地径流收集及膜下自流出滴灌溉技术可有效地收集丰雨期地表径流,就地储存,旱季利用自然高差灌入集水袋,经自流管进行膜下自流灌溉,可有效地提高该区降水利用率,有效地解决黄土高原地形破碎、渠系难以浇灌的难题.造林试验表明,该技术可明显地提高20～70 cm土层含水量,可使刺槐、油松、枣树造林成活率分达到97.7%、91.4%、90.5%,比对照分别提高了57.0%、77.8%和69.4%;结合幼树根基覆膜技术,在栽植第2年即可使刺槐、油松、枣树之主径分别比对照提高26.9%、55.2%和49.6%,树冠投影面积分别比对照提高90.9%、74.2%和51.8%.同时可明显地降低坡地土壤侵蚀模数,在降雨387 mm的情况下,处理区径流发生量及土壤侵蚀模数分别较对照下降38.3%和102.7%.具有良好的生态效益和社会效益,在立地条件差、地形破碎的黄土丘陵沟壑区是一项投资少、效益高、简单易行的抗旱新技术,在我国西北同类型干旱地区有着较好的推广前景.     

适宜节水灌溉模式抑制寒地稻田N_2O排放增加水稻产量

2014年在大田试验条件下,设置控制灌溉、间歇灌溉、浅湿灌溉及淹灌4种水分管理模式,采用静态暗箱-气相色谱法田间观测寒地水稻生长季N2O排放特征,研究不同灌溉模式对寒地稻田N2O排放的影响及N2O排放对土壤环境要素的响应,同时测定水稻产量,以期为寒地稻田N2O排放特征研究提供对策。结果表明:不同灌溉模式下N2O排放的高峰均出现在水分交替频繁阶段,水稻生育阶段前期,各处理N2O排放都处于较低水平,泡田期几乎无N2O排放。与淹灌相比,间歇灌溉使N2O排放总量增加47.3%,控制灌溉和浅湿灌溉使N2O排放总量减少40.7%和39.6%。寒地稻田N2O排放通量与土壤硝态氮含量关系密切,与土壤10 cm温度显著相关(P0.05)。水稻生长期间各处理N2O排放顺序间歇灌溉淹灌,二者均显著高于浅湿灌溉和控制灌溉(P0.05)。各处理水稻产量以浅湿灌溉最低、其他方式差异不显著。可见,间歇灌溉有助于提高水稻产量,但会促进稻田N2O的排放。在综合考虑水稻产量及稻田温室效应的需求下,控制灌溉为最佳灌溉方式,应予以高度重视。该研究可为黑龙江寒地稻作区选择节水减排模式提供科学支撑。     

灌溉方法对保护地土壤有机氮组分及剖面分布的影响

用Bremner有机氮分组法测定了连续7年采用不同灌溉方法灌溉的保护地土壤各剖面层次有机氮组分含量。结果表明,土壤全氮及有机氮各组分含量均随土层深度的增加而降低,但有机氮各组分占全氮的比例随土层深度增加的变化却无明显规律。用3种灌溉方法灌溉,不同土层间土壤有机氮各组分含量的差异主要存在于0～50 cm土层,50 cm以下差异很小;相同土层,土壤有机态氮含量均以酸解氮为主,且酸解氮中各组分绝对含量和相对含量的大小排列顺序均为,未知态氮〉氨态氮〉氨基酸态氮〉氨基糖态氮。在0～80 cm土层,土壤酸解氮占全氮的比例大多在58%～60%之间,只有渗灌处理0～10 cm,10～20 cm及沟灌处理0～10 cm土层酸解氮占全氮的比例较低,分别为34.21%,50.75%和48.02%;而非酸解氮占全氮的比例大多在32%～36%之间。3种灌溉方法相比较,除个别层次外,酸解氮中氨基酸态氮、氨基糖态氮及氨态氮占全氮的比例在各土层中滴灌和渗灌处理均高于沟灌处理,而酸解未知态氮和非酸解氮占全氮的比例则为沟灌处理高于滴灌和渗灌处理。     

The impact of environmental change on the intensity and spatial pattern of water erosion in a semi-arid mountainous Andean environment

Aerial photographs taken in 1976 and 1989 and a field survey in 1999 showed that land use in a 900-ha catchment in the southern part of the Ecuadorian Andes is highly dynamic. Over 23 years, ca. 83 ha of arable land was abandoned and ca. 70 ha was taken into agricultural production. Changes in land use were not spatially homogeneous. Parcels on unstable geologic formations and close to village centres were preferably set-aside. Land taken into cultivation was preferably located on gently sloping areas close to newly built sites and arterial roads. The area with bush vegetation increased by regeneration of natural vegetation on fields set-aside in the late 1970s and early 1980s. There was a complex interaction between water erosion and environmental change in the study area. Land taken into production was levelled for furrow irrigation: this led to a net reduction in the area susceptible to water erosion. However, one quarter of the area affected only by sheet and rill erosion 23 years ago has since become incised by deep gullies. This increase in gully density was related to inadequate construction and management of irrigation infrastructure, rather than to change in vegetation cover and/or soil erodibility caused by agricultural practices. This factor is often overlooked in studies of the effects of environmental change on geomorphologic processes.     

北方旱作区小流域截潜流集水高效利用研究

论述了北方旱作区寿阳白马河流域截潜流集水工程的结构和功能特点,研究了截潜流集水效果和高效利用技术的途径和措施。为北方同类型区域综合利用区域水资源提供参考。     

引水灌溉工程水土保持方案研究——以青海湟水北干渠扶贫灌溉一期工程水土保持方案设计为例

 引水灌溉工程开发建设项目,在施工中产生的水土流失,具有一定的特殊性;其水土保持方案设计,也有一定的规律可循。以青海省湟水北干渠扶贫灌溉一期工程水土保持方案设计为例,对建设过程中可能产生的水土流失的特点及可能造成的水土流失危害等进行分析,并结合工程实际,采用分类整治的方法,提出治理方案。这对其他同类工程水土保持方案的设计具有一定的借鉴意义。     

河北省曲周盐渍化地区微咸水灌溉对土壤环境效应的影响

在田间条件下，利用微咸水和淡水对河北省曲周盐渍化地区冬小麦进行灌溉试验，对冬小麦耗水量及其构成以及土壤环境效应等方面进行了研究和分析。两年的研究结果表明在小麦生长季灌溉过多，不利于作物根系深扎，不能充分利用土壤水分，造成水资源的浪费。利用微咸水进行灌溉增加了土壤盐分，使土地质量有着潜在恶化的趋势；在小麦收获时土壤表层溶液电导率可达10 dS/m左右，如不采取适当的田间管理措施，土壤盐分将危害下一季作物生长。如合理利用，可充分发挥此地区地下浅层微咸水资源的生产潜力，可缓解该地区的水资源紧张，促进农业发展；但微咸水灌溉的长期土壤环境效应需进一步研究。     

RESPONSES OF WHEAT PLANTS IN TERMS OF SOIL WATER CONTENT,BULK DENSITY,SALINITY, AND ROOT GROWTH UNDER DIFFERENT PLANTING SYSTEMS AND VARIOUS IRRIGATION FREQUENCIES

The effects of irrigation water rates and seed bed shapes on changes in soil water and salinity status, bulk density, root growth and dry matter (DM) weights of wheat plants (Triticum aestivum L.) were investigated with a split plot design in a field trial in Zahak Agricultural Research Station in Sistan, Iran in 2005. Irrigation intervals after 80 and 160 mm evaporation from class A evaporation pan were used as main plot. Flat surface, single, triple, and six-row beds with a 20 cm row space were used as subplots. Each treatment was replicated four times. Volumetric soil water content and soil electrical conductivity (EC) were measured using Time Domain Reflectometry (TDR) at 0 —20, 20 —40 and 40 —60 cm depths at nine different times during the growing season. Soil water contents were also measured at 0 —10 and 10 —20 cm depths using standard sampling rings at four different times. The three and six-row beds increased the EC of the saturated paste extract with the more frequent irrigation intervals in this coarse textured soil. Soil water content, DM, and root density were always greater with the more frequent irrigations (shorter irrigation intervals). Root density was greatest in 0 —20 cm depth with the single row bed treatment. Grain yield and root density were greatest with single row bed treatment due to the bed shape at the root development stage (possibly due to a reduced mechanical resistance). A greater soil water content by the short irrigation interval increased grain yield and root density via reducing mechanical resistance. With the loamy sand, bulk density and mechanical resistance increased rapidly after cultivation. Bed shape at root development stage might have enhanced root growth and the crop yields. Apparently, mechanical resistance was the most limiting factor with these loamy sand soils than salinity.