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31.
晒田强度和穗肥运筹对三角形强化栽培水稻光合生产力和氮素利用的影响 总被引:2,自引:0,他引:2
以杂交中稻组合II优498为材料,在三角形强化栽培(TSRI)条件下,研究3种晒田强度(0~20 cm土壤相对含水量为80%±5%、60%±5%和40%±5%,分别记为W1、W2和W3)和3种穗肥运筹(晒田复水后第1、8和15天施用第1次氮素穗肥,分别记为S1、S2和S3)对灌浆结实期水稻光合生产和氮素利用的影响。结果表明,晒田程度和穗肥运筹对水稻光合生产、干物质积累、氮素积累、转运和利用和产量的影响存在显著互作效应,且晒田影响最为显著,氮素穗肥运筹次之。轻度晒田(W1)复水后第1天施用第1次氮素穗肥会降低抽穗后15 d和30 d的群体光合和有效穗数,推迟至复水后第8天或第15天施用第1次氮素穗肥可以提高抽穗后15 d和30 d的群体光合、收获指数和氮素稻谷生产效率;中度和重度晒田(W2和W3)复水后第1天和第8天施用第1次氮素穗肥可以提高孕穗期和齐穗期剑叶Pn和抽穗后15 d和30 d的群体光合、干物质积累、籽粒产量及构成指标、稻株氮素积累与利用。经过分析比较得出,TSRI模式下W2S1为晒田强度和穗肥运筹的最优组合,产量达到10.96 t ha-1。 相似文献
32.
灌区土壤盐渍化发展模拟预测与对策研究 总被引:8,自引:0,他引:8
以秦王川灌区观测和调查资料为依据,采用目前广为实用的MODFLOW地下水模拟软件,对灌区地下水动态进行了预测和分析,并对地下水质的发展趋势作出评价。灌溉实施以来,秦王川灌区地下水位逐年上升。未来10年内盐沼区面积扩大约为28 km2,并且将继续增加,地下水埋深0~2 m的面积达31.4 km2,占灌区面积的比例约为6%。未来20年地下水埋深0~2 m的面积达47 km2,占灌区面积的比例为10%左右。根据地下水位的变化特征,对控制土壤盐渍化发展的因素和对策进行了分析,提出以明沟排水为主,加大灌区下游地下水排泄能力;以渠灌为主,适度发展井灌,大力推行田间节水灌溉技术等对策。 相似文献
33.
在分洪区内存在河渠的情况下,根据水流在河渠外区域和河渠内运动特点的不同,对已有的分洪区二维水流数学模型进行拓展,建立了相应的数学模型。该模型计算时能考虑河渠两侧有、无堤防两种情况,通过对概化地形的计算,证明了模型的合理性。 相似文献
34.
Evaluating a multi-level subsurface drainage system for improved drainage water quality 总被引:1,自引:0,他引:1
This paper describes a multi-level drainage system, designed to improve drainage water quality. Results are presented from a field scale land reclamation experiment implemented in the Murrumbidgee Irrigation Area of New South Wales, Australia. A traditional single level drainage system and a multi-level drainage system were compared in the experiment in an irrigated field setting. The single level drainage system consisted of 1.8 m deep drains at 20 m spacing. This configuration is typical of subsurface drainage system design used in the area. The multi-level drainage system consisted of shallow closely spaced drains (3.3 m spacing at 0.75 m depth) underlain by deeper widely spaced drains (20 m spacing at 1.8 m depth). Data on drainage flows and salinity, water table regime and soil salinity were collected over a 2-year period. 相似文献
35.
不同灌排模式稻田排水中氮磷流失规律 总被引:6,自引:0,他引:6
为了研究不同灌排模式稻田排水中氯磷流失规律,以集成合理的节水灌溉与控制排水技术,在江苏高邮开展田间试验.试验区排水斗沟出口处设水位调控闸门,在水稻不同生育阶段对排水沟水位及田间水分进行控制,形成新型的控制灌排模式.与常规灌排模式进行对比,两年田间试验成果表明,控制灌排模式较常规灌排模式节水16.7%,增产7.1%,排水总量减少54%,水稻全生育期稻田排水中NH4+;-N、NO3-N与TP流失总量分别减少38.07%、82.29%和52.15%,节水减排和降污效果显著.采用控制灌排模式,通过实施灌水调控和排水管理.控制了氮磷流失关键时期的排水量.高效利用了水分和养分,取得了节水高产、减排控污的效果. 相似文献
36.
北京市针对水源地治理问题提出了构筑"生态修复、生态治理、生态保护"三道水源防线的发展模式.通过2006年7月至2008年7月的实地野外试验,对北京市重要水源地密云水库源区曹家路流域的农业面源污染、有机物污染情况等进行了跟踪调查和研究.研究结果反应出北京市水源地水土保持及清洁小流域治理工程的效果明显,并给出了该水源地今后治理与发展的建议. 相似文献
37.
灌区是我国粮食安全和现代农业发展的基础保障,同时也是区域经济发展和生态环境保护的重要基石。然而西北地区独特的气候、地貌及社会经济状况导致了灌区生产能力和生态服务功能难以满足现代生态农业发展的需求。通过系统分析西北灌溉农业发展中面临的水资源过度开发、土壤盐碱化严重、生态环境功能低下等方面的问题,阐述了西北现代生态灌区的内涵与特征,并基于农业生产“功能水分”来源,将西北灌区划分成了灌溉依赖型灌区、灌溉主导型灌区、灌溉补充型灌区和灌溉提质型灌区4类。以灌区农业生产系统、物能输配系统、生态环境系统为建设对象,提出了灌区生态服务功能优化配置、灌区农田物能调控和灌区生态系统安全评估三大核心理论,构建了灌区系统控污与景观价值提升技术、灌排系统管控技术、作物生境要素综合调控技术三大关键技术,从而形成了西北现代生态灌区理论与技术保障体系,为我国西北灌溉农业高质量可持续发展提供理论与技术指导。 相似文献
38.
为了探究不同外包滤料条件下的暗管排水性能和土壤脱盐效果,基于室内试验研究成果,在田间设置4种暗管排水系统(各系统中暗管埋深均为80 cm,间距均为20 m),所用外包滤料分别为68 g/m2土工布(L)、砂滤料(S)、68 g/m2土工布+砂滤料(LS)和无外包滤料(W),以当地常规明沟排水(CK)作为对照,通过田间试验分析了春灌过程中各暗管系统的排水性能指标及土壤脱盐效率.结果表明:相比处理W,处理L,S和LS平均排水速率提升了7.44%,12.55%和15.75%,平均流量衰减度降低4.07%;处理S和LS累积排水量提高了5.11%和8.31%(P<0.05).各暗管处理春灌后平均土壤脱盐率均达47%以上,较CK提升显著,其中处理LS效果最优,为50.94%.综上,应优先选择处理LS作为河套灌区暗管排水系统外包滤料布设方案.该研究结果可为河套灌区暗管排盐技术的推广应用提供理论支撑和科学指导. 相似文献
39.
Nigel W.T. Quinn 《Agricultural Water Management》2009,96(3):484-492
Many perceive the implementation of environmental regulatory policy, especially concerning non-point source pollution from irrigated agriculture, as being less efficient in the United States than in many other countries. This is partly a result of the stakeholder involvement process but is also a reflection of the inability to make effective use of Environmental Decision Support Systems (EDSS) to facilitate technical information exchange with stakeholders and to provide a forum for innovative ideas for controlling non-point source pollutant loading. This paper describes one of the success stories where a standardized Environmental Protection Agency (EPA) methodology was modified to better suit regulation of a trace element in agricultural subsurface drainage and information technology was developed to help guide stakeholders, provide assurances to the public and encourage innovation while improving compliance with State water quality objectives. The geographic focus of the paper is the western San Joaquin Valley where, in 1985, evapo-concentration of selenium in agricultural subsurface drainage water, diverted into large ponds within a federal wildlife refuge, caused teratogenecity in waterfowl embryos and in other sensitive wildlife species. The fallout from this environmental disaster was a concerted attempt by State and Federal water agencies to regulate non-point source loads of the trace element selenium. The complexity of selenium hydrogeochemistry, the difficulty and expense of selenium concentration monitoring and political discord between agricultural and environmental interests created challenges to the regulation process. Innovative policy and institutional constructs, supported by environmental monitoring and the web-based data management and dissemination systems, provided essential decision support, created opportunities for adaptive management and ultimately contributed to project success. The paper provides a retrospective on the contentious planning process and offers suggestions as to how the technical and institutional issues could have been resolved faster through early adoption of some of the core principles of sound EDSS design. 相似文献
40.
In Ethiopia vertisols cover about 10% of the total land area and is the fourth most important soil used for crop production, accounting for nearly 23% of the total arable land used for crop production. More than half of the vertisols are found in the Central Highlands of Ethiopia, with an altitude of more than 1500 m above mean sea level. The unique physical and chemical properties of these soils and the high rainfall during the main cropping season create severe surface waterlogging problems which hinder crop production activities. Severe surface waterlogging affects the growth of plants by impeding nutrient uptake and creating oxygen deficiency around the root zone. To address this crop production problem, three surface water drainage methods, namely broad bed and furrow (BBF), ditch, and flat (traditional) methods were evaluated using the water balance of the plant root zone and wheat as a test crop. The experiment was conducted at the Ginchi Research Station in the central highlands of Ethiopia over two consecutive seasons (2000 and 2001). The results showed that both the BBF and the ditch drainage methods gave about 33% and 22% more grain yield than the flat treatment, respectively. However, there were no significant differences between BBF and ditch for both grain and biomass yield during both experimental seasons. During both seasons the total water balance (ΔWr) at the root zone especially, in the months of June, July and August on all the treatments was higher than the crop water requirement (ETc) and showed no significant difference between the treatments. Thus, the results of this study indicated that the soil water in the root zone was not significantly altered by surface drainage systems and therefore implies the need of further improvement of the different surface drainage methods regarding improving the waterlogging condition and hence the productivity of the vertisols in the Central Highlands of Ethiopia. 相似文献