排序方式: 共有26条查询结果,搜索用时 343 毫秒
1.
2.
3.
Abubaker B. Ali Yan Haofang Li Hong Wu Yan You Nazar A. Elshaikh Gameraldawla Hussein 《Communications in Soil Science and Plant Analysis》2019,50(1):49-64
Biochar has recently received increased attention because it improves poor soil fertility. However, its potentiality to enhance soil physical properties under water stress conditions not yet deeply investigated. Hence, extensive field investigations were carried out to study the effects of biochar addition (BA) with deficit irrigation (DI) on soil bulk density (BD), porosity percentage (P%), soil moisture content (SMC%), soil hydraulic conductivity (K), cucumber yield and water use efficiency (WUE) during two consecutive seasons (2016 and 2017). The biochar treatments were B0 (0 ton ha?1), B1 (10 ton ha?1and B2 (20 ton ha?1), while the DI treatments were 1.0 (W1), 0.60 (W2) and 0.40 (W3) of the reference evapotranspiration (ET0). The parameters were measured at soil depths of 0–10 (d1), 10–20 (d2) and 20–30 cm (d3) for measurement periods of before sowing (P1), mid-season (P2) and after harvest (P3). The results showed that the B2W1 combination gave the highest yield (57 and 45.2 t ha?1), WUE (10.94 and 11.27 kg m?3), SMC (39.2 and 40.1%) in both seasons, respectively. The B2W3 had the highest porosity (47.5 and 46.1%) values at the d1. Meanwhile, the lowest soil BD values of 1.1 and 1.05 g cm?3 were obtained by the B2W1 at d1 for 2.16 and 2017, respectively. Statistically, most of the parameters studied under B2W2 and B0W1 had non-significant differences between them. Hence, the addition of biochar with DI could be an integrated approach to address the drought stress, while enhancing soil and plant properties. 相似文献
4.
Penman-Monteith模型模拟Venlo型温室黄瓜植株蒸腾 总被引:2,自引:2,他引:0
准确模拟温室作物蒸腾对于制定科学合理的灌溉制度及温室环境调控具有重要意义,该研究基于2017年秋冬季和2018年春夏季Venlo型温室黄瓜生育期内微气象数据、黄瓜生长发育指标和植株蒸腾,对Penman-Monteith(PM)模型中关键参数—冠层阻力和空气动力学阻力进行研究。通过分析黄瓜叶片孔阻力与温室内气象因子的响应关系,构建了由黄瓜有效叶面积指数及叶片孔阻力模拟冠层阻力的子模型;采用基于风速的Perrier对数法和基于温室对流类型的热传输系数法计算温室内低风速环境下的空气动力学阻力,并评价不同方法的适用性。结果表明:叶片孔阻力与太阳辐射呈指数关系(R~2=0.89),可通过观测温室内太阳辐射计算黄瓜叶片孔阻力;应用热传输系数法确定空气动力学阻力时,温室内对流类型绝大多数时间为混合对流;2种方法计算的温室内空气动力学阻力变化幅度均较小,Perrier对数法计算的春夏季和秋冬季空气动力学阻力平均值分别为388和383 s/m,热传输系数法计算的空气动力学阻力平均值分别为141和158 s/m;基于2种空气动力学阻力计算方法,PM模型模拟的植株蒸腾与实测值均具有较好的一致性,但采用Perrier对数法计算空气动力学阻力时,PM模型低估了植株蒸腾,春夏季和秋冬季拟合线斜率分别为0.87和0.91;而采用热传输系数法计算空气动力学阻力时,PM模型可更准确的模拟该地区温室黄瓜植株蒸腾,春夏季和秋冬季拟合线斜率分别为1.00和0.94,R~2分别为0.91和0.95,均方根误差分别为46.15和12.45 W/m~2。该研究结果为实现PM模型在Venlo型温室环境的准确应用提供了参考。 相似文献
5.
Paddy and Water Environment - Models for predicting hourly canopy resistance (r c) and latent heat flux (LET) based on the Penman–Monteith (PM) and bulk transfer methods are presented. The... 相似文献
6.
基于修正双作物系数模型估算温室黄瓜不同季节腾发量 总被引:6,自引:5,他引:1
为估算温室黄瓜植株蒸腾与土面蒸发,该研究基于FAO-56推荐的双作物系数模型,应用温室内实测微气象、叶面积指数(LAI)及土壤水分数据,对模型中基础作物系数(Kcb)和土面蒸发系数(Ke)进行修正,并基于修正后FAO-56Penman-Monteith(P-M)模型,确定温室参考作物蒸发蒸腾量(ET0),进而估算温室黄瓜蒸发蒸腾量(ETc)和植株蒸腾(Tr)。基于Venlo型温室内黄瓜不同种植季节(春夏季和秋冬季)Lysimeter和茎流计观测的黄瓜ETc和Tr,对修正后的双作物系数模型预测结果进行验证。结果表明,应用修正后的双作物系数模型估算的温室黄瓜ETc和Tr与实测值具有较好地一致性,春夏季温室黄瓜全生育期ETc估算值与实测值的日均值分别为3.05和2.94 mm/d,秋冬季分别为2.53和2.76 mm/d。修正后的双作物系数模型估算春夏季温室黄瓜日ETc的决定系数(R2)、均方根误差(RMSE)和模型效率系数(Ens)分别为0.95、0.41 mm/d和0.93;估算秋冬季ETc的误差计算结果依次为0.91(R2)、0.48 mm/d(RMSE)和0.90(Ens)。修正后的双作物系数模型估算春夏季日平均Tr与实测值分别为2.37和2.19mm/d,秋冬季分别为1.43和1.34 mm/d。研究结果还显示,不同种植季节温室黄瓜全生育期日平均Tr占ETc的比例分别为64.62%(春夏季)和68.59%(秋冬季)。该研究成果不仅为制定准确的温室黄瓜灌溉制度提供了理论依据,而且对实现温室环境智能化控制及减少温室内无效的土面蒸发具有重要意义。 相似文献
7.
微喷灌结合滴灌对温室高温环境和作物生长生理特性的影响 总被引:4,自引:3,他引:1
微喷灌结合滴灌是指在作物根区滴灌的基础上对作物冠层进行微喷灌来改善作物生长环境的一种灌水方式。为了探明微喷灌结合滴灌(micro-sprinkler irrigation combined with drip irrigation,MSDI)和地表滴灌(surface drip irrigation,SDI)2种灌水方式下温室高温环境及作物生长生理特性的差异及响应规律,该研究以黄瓜为试验对象,于2017年2-6月开展了2种灌水方式下温室环境及黄瓜生长生理特性的观测试验。结果表明:在改变温室环境方面,MSDI灌水方式较SDI可增加温室内相对湿度,降低气温,同时降低叶片温度约4℃;在作物生长生理特性方面,采用MSDI可增加黄瓜株高与茎粗,降低作物茎流速率,促进黄瓜生长;2种灌水方式下黄瓜最大光合效率几乎一致,分别为0.74和0.77,但日平均实际光合效率差异明显,分别为0.57和0.47,MSDI灌水方式下黄瓜叶片日平均气孔导度和光合速率比SDI方式分别高182.8%和92.4%。该研究成果对于合理调控温室高温环境、提高温室作物产量具有重要的指导意义。 相似文献
8.
9.
Ransford Opoku Darko Shouqi Yuan Li Hong Junping Liu Haofang Yan 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2016,66(3):191-206
Water scarcity in agriculture is becoming a major problem due to increasing demand from nonagricultural uses and intensive crop management on existing croplands to meet the needs of an expanding global population. Efficient use of the available irrigation water is therefore of important concern. Even though intensive research in the areas of crop physiology, irrigation engineering, agronomy and agricultural economics has developed several ways to improve the efficiency of irrigation water, a multidisciplinary approach is often regarded as the best future path to achieve further enhancements in meeting the forthcoming challenge of producing more and safety foods. Failure of irrigation production has profound effects on the welfare of all those employed in it and also their customers. Indeed, the scale of the industry is such that world food prices will be influenced by the overall performance of the irrigation farmers, but low food prices are essential to the welfare of the poorest people. The contribution of irrigation and water management to increased food production must come through both expansion of irrigation and improved management of existing water supplies. This review presents the past, current and future panorama of irrigation as a viable tool in ensuring food security on the globe. Considering past trends, this review empathizes that future irrigation technologies should be focused on providing the leadership and capacity to capture, develop and promote new irrigation practices and management systems to optimize production. 相似文献
10.