浅谈如何实现农业高效节约用水

主要介绍如何节约农业灌溉用水及提高用水效率的几种措施。     

不同灌溉和施肥方式对杂交稻生长和根际环境的影响

对杂交稻中优218不同灌溉方式和氮肥管理下水稻生长和根际环境的变化进行研究,结果表明,水稻好气灌溉条件下各施肥处理产量均高于传统灌溉处理,产量比淹水灌溉增产10.5%~11.3%,主要表现在每穗粒数增加而提高产量。好气灌溉与淹水灌溉比较各生育期地上部干物重和叶面积指数均增加,土壤氧化还原电位提高,放线菌数量显著增加。增加有机肥降低土壤氧化还原电位和提高放线菌数量,在好气灌溉条件下施相同氮素有机肥放线菌数多于化肥。     

发展山园瓯柑节水喷灌机械配套节本增效技术

随着我国综合国力的稳步发展,城乡人民的生活水平也不断提高,发展瓯柑种植面积和提高产量,改善瓯柑品质,是人们物质生活的需要,也是我国新形势下农业产业结构调整的发展趋势,并带动山区农民共同致富,利国又利民。本文就温州地区发展山园瓯柑节水喷灌机械配套节本增效技术进行叙述,对于推广应用具有重要的现实意义。     

温室智能灌溉控制系统的应用研究与展望

当前,智能灌溉控制系统多采用定时控制,即到达开启时间,设备工作,达到灌溉时长,设备停止,在一定程度上实现了自动化灌溉,但由于作物在不同生长时期的需水量不同,灌溉控制系统难以生成与作物需求一致的灌溉方案。我国温室智能灌溉技术起步较晚,还没有大范围应用,而已经采用智能灌溉的地区,其控制方式及控制策略也不同。本文以智能灌溉控制系统为出发点,阐述了温室智能灌溉控制系统的组成、问题等,并展望了其未来的发展。     

灌溉模式对红壤稻田土壤环境及水稻产量的影响

为优化红壤丘陵区水稻生产的水分管理模式,以中国科学院桃源农业生态试验站长期田间定位试验为研究对象,模拟分析了江南红壤丘陵区4种不同灌溉模式对稻田的土壤环境及系统生产力的影响。结果表明,土壤环境方面,雨养稻田与模拟节水灌溉相比,水稻生育期白天平均土壤温度高0.3～0.5℃;长期淹灌红壤稻田土壤体积质量相对较低,土壤蓄水能力较强,有利于土壤有机质的累积和氮素质量分数的提高,淹灌表层（0～20 cm）土壤全氮质量分数较雨养和湿灌分别高10.8%和8.8%,土壤有机质质量分数分别高7.0%和6.1%。由于江南丘陵区降雨资源丰富,早稻期间雨量充沛,处理间早稻产量差异主要来自不同灌溉模式下土壤环境尤其是土壤养分条件的改变;晚稻期间,水分则成为水稻产量提高的限制因子,雨养区晚稻产量显著低于其他灌溉处理。相对于其他水分管理模式,红壤双季稻田淹水灌溉模式能够获得更高的水稻产量。     

微灌地膜的节水保墒增温效应研究

在实验基础上 ,分析论述了微灌地膜的节水效果和增温保墒效应。试验结果表明 ,微灌地膜可比地面灌溉节水 61 % ,增加地温 3℃～ 6℃ ,近地面空气相对湿度提高 3 0 %～ 40 % ,综合效应明显。可供微灌地膜或膜下微灌的进一步研究设计参考     

温室增温和灌溉量变化对棉花产量、 生物量及水分利用效率的影响

为了解气候变化对棉花生长的影响,在2011—2012 年,通过2 个温室进行增温和灌溉量变化的试验（一个温室用红外灯管增温,另一个不增温）,每个温室设田间灌溉量的0.7 倍、0.85 倍、1 倍、1.15 倍、1.3 倍5 个灌溉水平,研究增温和灌溉量对产量、生物量及水分利用效率的影响。结果表明,棉花生长季平均温度增加1~3.5℃有利于产量的增加,生长季、花期和铃期温度升高1℃,产量分别增加200.694、225.732、109.838 kg/hm2,而蕾期温度升高1℃却会降低产量162.814 kg/hm2。生长季和蕾期增温1℃会分别降低生物量1079.2、1179.8 kg/hm2,降低产量和干物质的水分利用效率3.4215、2.8098 kg/(hm2·mm)。灌溉倍数每增加1 倍,产量和生物量分别增加734.51、2242.3 kg/hm2。但增温会增加水分的消耗量,这对于处于干旱区的新疆来说是不利的。随着气候变暖,棉花耗水增大,产量增加。     

Potential for the alleviation of arsenic toxicity in paddy rice using amorphous iron-(hydr)oxide amendments

Abstract

A pot culture experiment was conducted to investigate the effects of amorphous iron-(hydr)oxide (Am-FeOH) amendments on arsenic (As) availability and its uptake by rice (Oryza sativa L. cv. BR28) irrigated with As-contaminated water. A rhizobag system was established using 3.5 L plastic pots, each containing one central compartment for plant growth, a middle compartment and an outside compartment. Three levels of laboratory-synthesized Am-FeOH (0, 0.1 and 0.5% w/w) were used to amend samples of the As-free sandy loam paddy soil placed into each compartment of the rhizobag system. The soils were submerged with a solution containing 5 mg L^?1 As(V). Two-week-old rice seedlings were planted in the central compartments and cultured for 9 weeks under greenhouse conditions. The addition of 0.1% Am-FeOH to the soil irrigated with As-contaminated water improved plant growth, reduced the As concentration in the plants and enhanced Fe-plaque formation on the root surfaces. Analysis of soil solution samples collected during the experiment revealed higher pH levels and lower redox potentials in the soils amended with Am-FeOH at the onset of soil submergence, but later the soil solution collected from the 0.1% Am-FeOH treatment was slightly acidic and more oxidized than the solution from the 0% treatment. This indicated active functioning of the roots in the soil treated with 0.1% Am-FeOH. The concentrations of As(III) in the soil solution collected from the central compartment were significantly reduced by the Am-FeOH amendments, whereas in the soil treated with 0% Fe, As(III) accumulated in the rhizosphere, particularly during the late-cultivation period. The improvement in plant growth and reduction in As uptake by plants growing in the Am-FeOH treated soil could be attributed to the reduction of available As in the soil solution, mainly as a result of the binding of As to the Fe-plaque on the root surfaces.     

施磷对限水灌溉小麦根冠及产量的影响研究

试验研究结果表明 ,盆栽限水灌溉时施P明显促进小麦幼穗、根系和株高的早期生长发育 ,而对叶片含水量和叶绿素含量的影响较小 ;施P明显提高小麦地上部干物质量和产量 ,且以限水处理效果最明显 ,提高了限水处理“温麦 6”根干物质量以及“温麦 6”和“冀麦 36”穗数     

Water Requirements of Safflower Entries in Middle Egypt

Two promising selected land races of safflower ( Carthamns tinctorious L.) designated as line 11 and line 13, together with the local variety Giza 1 , were examined under three levels of moisture depletions, i.e. 40, 60 and 80 % ASMD at Fayoum, Middle Egypt during 1986/87 and 1987/88 seasons. In both growing seasons, the second irrigation treatment i.e. 60 % ASMD gave the highest means for growth characters as well as seed yield and most of its components. Seed oil content per cent exhibited an increased as soil moisture depletion increased with no significant difference between entries. Safflower entries showed clear differences in some yield components which compensate each other and resulted in no significant difference in seed yield per hectar.
Consumptive use of water by safflower plants increased as the available soil moisture around the root zone increased. No significant differences were found in water consumed by safflower entries used in all experiments.
In the two experimental seasons, the best water use efficiency (WUE) for seed production was obtained also from the second treatment (60 % ASMD). The line 11 gave the best WUE.