不同亏缺灌溉方式对冬小麦产量及水分利用效率的影响

【目的】优选适宜的小麦节水灌溉模式。【方法】采用田间小区试验,以生育期内灌越冬水、拔节水和开花水为对照(CK),设置了3种不同的亏缺灌溉模式:浇拔节水和开花水(T1)、拔节水+开花水隔畦交替灌溉(T2)、返青水+孕穗水+开花水隔畦交替灌溉(T3)。在拔节期和开花期,测定了小麦光合速率、蒸腾速率、棵间蒸发量、干物质量,并测定了小麦的产量和水分利用效率。【结果】T1处理小麦的光合速率与CK无显著差异,但蒸腾速率显著低于CK。在T2、T3处理中,干区、湿区的光合速率与CK也无显著差异,但干区小麦的蒸腾速率显著低于CK和湿区。各处理棵间蒸发量均显著低于CK。T2、T3处理中干区小麦的棵间蒸发量均显著低于湿区。T1处理提高了小麦花后干物质积累量,但花前干物质转移量减少。T2、T3处理湿区小麦花后干物质积累量高于CK,但花前干物质转移量显著低于CK。T2、T3处理干区小麦花后干物质积累量均显著低于湿区,但花前干物质转移均高于湿区小麦。T1、T2和T3处理对小麦产量没有显著影响,但均显著减少灌溉水量和作物的耗水量。【结论】3种时空亏缺灌溉模式均显著提高了小麦灌溉水利用效率和水分利用效率。     

滴灌施肥下水肥用量对温室土壤硝态氮残留的影响

【目的】通过水肥管理达到减少温室土壤硝态氮残留、维持土壤质量的目的,探求温室土壤硝态氮残留与水肥用量的关系。【方法】在滴灌施肥条件下,以灌水量和氮、磷、钾及有机肥用量为试验因素,根据当地日光温室番茄长季节栽培实际中的水肥用量,设计各试验因子的水肥水平,采用五元二次通用旋转组合设计进行试验。拉秧后测定耕层土壤硝态氮量,建立土壤硝态氮量与水肥因子间的数学模型,据此分析了各单因子效应及二因素的耦合效应。【结果】施氮量对土壤硝态氮残留量影响最大,施磷量、灌水量和施钾量次之,有机肥用量最小。当其他因子为0水平时,土壤硝态氮残留量随氮肥用量的增多而增加,随施磷量呈开口向上的抛物线变化,随灌水量、施钾量以及有机肥用量呈开口向下的抛物线变化。灌水量及氮、磷、钾和有机肥用量对土壤硝态氮残留产生的影响程度随其他因子的水平而变,存在明显交互作用。模型寻优显示:灌水量455.1～471.5 mm,施氮量532.3～586.5 kg/hm2,施磷量420.8～466.4 kg/hm2,施钾量646.1～723.5 kg/hm2,有机肥用量25.6～27.9 t/hm2,耕层土壤硝态氮量可维持在100～150 mg/kg的较低水平。【结论】温室菜地土壤硝态氮残留量相对较大,可以通过优化水肥用量来减少土壤硝态氮的残留,故在滴灌施肥条件下仍需严格控制水肥用量。     

不同灌水条件下施氮量对滴灌夏棉冠层指标的影响

[目的]揭示施氮量对滴灌夏棉冠层指标的调控作用。[方法]设置3个灌水水平(滴灌,灌水定额30、22.5、15mm,分别记为I1、I2、I3)和5个氮素水平(0、60、120、180、240kg/hm2,分别记为N0、N1、N2、N3、N4),研究了不同灌水条件下施氮量对株高、叶面积指数、叶片含氮量和比叶重的影响。[结果]I2条件下,株高和叶面积指数随施氮量增加呈不断增加趋势,施氮量为240kg/hm2时达到最大。I1和I3条件下,增加施氮量,株高和叶面积指数先增加后减小,在施氮量为60或120kg/hm2的处理达到最大。夏棉比叶重和叶片含氮量随着生育期推进分别呈不断上升和不断下降趋势,5个施氮水平下夏棉叶片比叶重均表现为I1相似文献   

土壤基质势调控对温室滴灌番茄土壤水分分布和产量的影响

【目的】指导设施蔬菜生产中科学合理地利用滴灌技术进行灌溉。【方法】采用小区试验的方法,以冬春茬番茄为研究对象,布置了7个不同土壤基质势阈值的试验,在番茄开花坐果期和结果期分别控制滴头正下方20 cm深度土壤基质势在-15和-15 kPa(S1)、-15和-30 kPa(S2)、-15和-45 kPa(S3)、-25和-25 kPa(S4)、-30和-15 kPa(S5)、-30和-30 kPa(S6)以及-30和-45 kPa(S7),研究了日光温室滴灌土壤基质势调控下土壤水分随时间变化及空间分布的规律,以及番茄产量、畸形果率和灌溉水利用效率等。【结果】①控制滴头正下方20 cm深度土壤基质势可以明显影响0～100 cm深度土壤水分状况。②在番茄开花坐果期,当土壤基质势阈值控制在-30 kPa或更高时,番茄根系主要吸收利用0～60 cm深度以上范围的土壤水分,70 cm深度以下土壤水分基本不变,0～60 cm深度土壤体积含水率平均为28.6%,为田间持水率的84%,60～100 cm土壤体积含水率平均为36.2%,为田间持水率的90%。③番茄进入结果期后,当土壤基质势阈值控制在-25～-15 kPa时,整个土体土壤含水率基本保持在田间持水率的77%～91%,根系主要吸收利用0～60 cm深度以上范围的土壤水分,70 cm深度以下土壤水分消耗缓慢;当土壤基质势阈值降低到-45～-30 kPa时,根系吸收利用到80～100 cm深度的土壤水分,整个土体土壤含水率不断降低,降低到田间持水率的60%～66%。④不同处理番茄产量、畸形果率和灌溉水利用效率有明显差异,其中S3和S7处理番茄产量高,S5处理产量低;S1、S3和S4处理的畸形果率大,S6和S7处理的畸形果率低;S1处理的灌溉水利用效率最低,S7处理的灌溉水利用效率最高。【结论】日光温室少量高频滴灌条件下,当滴头正下方20 cm深度土壤基质势阈值开花坐果期控制在-30 kPa、结果期控制在-45 kPa时,整个土体土壤水分状况基本良好,番茄的产量高,畸形果率低,灌溉水利用效率高。     

Enhancement of Depleted Loam Soil as Well as Cucumber Productivity Utilizing Biochar Under Water Stress

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.     

Effects of Different Irrigation Levels and Arbuscular Mycorrhizal Fungi (AMF), Photosynthesis Activator,Traditional Fertilizer on Yield and Growth Parameters of Dry Bean (Phaseolus Vulgaris L.) in Arid Climatic Conditions

A field experiment has been conducted to determine the effects of different irrigation water and AMF (Arbuscular Mycorrhizal Fungi) biofertilizer, photosynthesis activator and traditional fertilizer dry bean (Phaseolus vulgaris L.) on yield and growth parameters in Nevsehir Province of Turkey in 2015. The experiment has been carried out using three replications in a split plot design with three different irrigation types as main plots and AMF biofertilizer (ERS), photosynthesis activator (Multigreen-Mg), traditional fertilization (TF-Control), ERS + Mg, ERS + TF and TF + Mg applied as subplots. The number of pods per plant, the length of pods, the number of grains per pod, the weight of grains per plant, the yield of grains, 1000 seed weight, the number of grains per plant, protein yield, arbuscular mycorrhizal fungi rate have been evaluated as yield and growth criteria in the study. In the experiment, as well as the treatment x irrigation interaction, the plant height, pod number per plant, pod lenght, grain number per pod, grain weight per plant, grain yield, 1000 seed weight, grain number per plant, protein rate/grain, protein yield, root weight and AMF colonization parameters, were the other studied properties that were found to be significant. The results obtained were 877.6 mm for I₁₀₀ irrigation treatment, 512.2 mm for I₅₀ irrigation treatment and 40.19 mm water for I₃₀ irrigation treatment. Regarding the growth parameters of dry bean, the highest PH was in ERS + Mg (67.66 cm), the lowest PH was in ERS (54.33 cm); In I₅₀, the highest Plant Height (PH) was in ERS + Mg (65.66 cm), the lowest PH was in TF-Control (53.00 cm); and in I₃₀, the highest PH was in TF-Control (50.66 cm), and the lowest PH was again in ERS + Mg (44.33 cm). For protein yield (PY) value, ERS + Mg, ERS + TF, TF + Mg have been placed in the same group, in I₁₀₀ and I₅₀ irrigation treatment. The highest value was ERS + TF (34.90 kg da^?1) in I₁₀₀, The lowest value was TF-control (19.90 kg da^?1) in I₃₀ irrigation treatment. In terms of mycorrhiza colonization ratio, ERS has been ranked first in all irrigation treatments, while the highest mycorrhiza colonization has been observed in I₃₀ irrigation treatment (26.30%). ERS was followed by ERS + Mg (23.33%). As expected, the lowest mycorrhiza colonization ratio in all irrigation treatments have been observed in TF-control treatment, while the highest mycorrhiza colonization ratio has been respectively observed in I₃₀ and I₅₀ irrigation topics. The highest root weight (RW) in I₁₀₀ irrigation treatment was observed in ERS (15.06 g plant^?1) and it was observed in ERS (19.05 g plant^?1; 26.30 g plant^?1) in I₅₀ and I₃₀ irrigation treatments. The lowest RW in all irrigation treatments has been observed in TF + Mg (4.43 g plant^?1, 6.40 g plant^?1, 10.26 g plant^?1), respectively.     

Sowing date effects on dry matter remobilization and yield of triticale (Triticosecale wittmack) under late season drought stress

A 2-year field experiment using a randomized complete block design with the treatments arranged as split-split-plot with three replicates was conducted to investigate the effects of different sowing dates. Different irrigation regimes and different triticale cultivars were tested during 2014 and 2015 growing seasons. Under cutting off irrigation at the milk development stage, Sanabad with 46.2% had higher relative water content on December 3 sowing date. Assimilate remobilization in cutting off irrigation at dough development was more than that at milk development and Sanabad had the highest assimilate remobilization on 3 December sowing date in both years. In both years, Sanabad had the highest remobilization efficiency. The highest contribution of pre-anthesis assimilates to grain was obtained on 3 December sowing date in both years in Sanabad. Lower grain yield in Juanillo cultivar under cutting off irrigation, appeared to be due to reduction in remobilization efficiency, especially by cutting off irrigation at milk development stage in late sowing date. Overall, Sanabad was more tolerant to cutting off irrigation than Juanillo.     

不同灌水量与每穴直播粒数对滴灌水稻生长发育及产量的影响

【目的】探索滴灌水稻高产高效的适宜灌溉定额及播种量。【方法】本试验在新疆农业科学院国家灰漠土肥力与肥料效应监测基地进行,设置3个灌溉定额水平,分别为796 mm(W1)、938 mm(W2)、1 059 mm(W3),每穴直播粒数设为每穴8粒(D1)、14粒(D2)、20粒(D3)3个水平,观测比较不同生育期株高、叶面积指数、干物质积累量等生长指标,分析不同灌水量与每穴直播粒数对滴灌水稻生长发育、产量及水分利用效率的影响。【结果】灌水量与每穴直播粒数交互作用以组合W3D1株高、叶面积指数和干物质积累量最高,分别为83.46 cm、8.46和2 962.67 g/m2,交互作用达到极显著水平(p≤0.01);W3D1处理产量最高达到6 789.00 kg/hm~2,灌水量对产量的影响达到显著水平(p≤0.05);W3D1水分利用效率为最优组合达到0.65 kg/m3。每穴直播粒数为8粒时,与W1、W2处理相比,W3处理产量增幅为54.95%、30.24%;W3处理中,D1处理与D2、D3处理相比,产量增幅分别为19.11%、23.96%。【结论】在本试验条件下,W3D1组合灌溉水量及每穴直播粒数为最佳。     

人工补水促进侧柏林地的种子萌发及天然更新

随着侧柏(Platycludus orientalis)林进入中成熟龄阶段,其更新和健康经营问题逐渐凸显出来。【目的】解决侧柏林内土壤湿度不足、籽苗稀少的问题并确定最佳补水时期。【方法】依据山地水土汇集面、沟谷两侧和集水池周边侧柏籽苗较密集的现实,进行人工促进侧柏林地种子萌发和天然更新的研究,应用小穴整地、模拟天然下种、人工灌水和林地模拟育苗等手段。【结果】于2017年秋季在济南燕子山上成功地促生许多侧柏苗。侧柏种子成熟期林地土壤水分不足是种子萌发的限制性因素之一。【结论】秋季9月为灌溉补水人工促进侧柏种子萌发的关键期,在适宜的光照条件下,可以有效地促进林地种子萌发和籽苗存活。     

Calculation of Irrigation Infiltration Recharge Coefficient and Analysis of Influencing Factors in the Lower Reaches of Aksu River北大核心CSCD

【Objective】In order to obtain the irrigation infiltration recharge coefficient in the lower reaches of Aksu river and improve the numerical simulation accuracy of groundwater in the study area,the influencing factors of the irrigation infiltration recharge coefficient in this area were analyzed. 【Method】In this paper,field sampling and indoor irrigation experiments were carried out by selecting representative points under different irrigation schemes,vadose zone thickness and soil structure in the lower Aksu area,and numerical simulation of vadose zone flow was carried out in combination with Hydrus-1d. Hydrus-1d model was used to calculate irrigation inflow under this soil structure by changing irrigation schemes and vadose zone thickness. Change of seepage recharge coefficient. On the basis of the calculation results of the model,the relationship between irrigation schedule,aeration zone thickness and irrigation infiltration recharge coefficient is analyzed firstly,and then the main factors affecting irrigation infiltration recharge coefficient in soil structure are analyzed with the method of model calculation and mathematical statistics. 【Result】The results showed that the irrigation infiltration recharge coefficient ranged from 0.320 to 0.474 under drip irrigation and from 0.408 to 0.561 under border irrigation. The irrigation infiltration recharge coefficient varied under different irrigation schemes,while the irrigation infiltration recharge coefficient decreased with the increase of aeration zone thickness. The main factors affecting irrigation infiltration recharge are soil permeability coefficient,soil bulk density and initial soil water content. 【Conclusion】According to indoor experiment combined with numerical model to calculate the irrigation infiltration coefficient under different irrigation system range, it is concluded that the influence factors of irrigation infiltration coefficient of irrigation system, the thickness of the vadose zone and reflects soil permeability coefficient of soil structure, soil quality and soil initial moisture content, volume for the downstream area irrigation infiltration coefficient selection in arid areas and provides the theory basis for further research. © 2019 Journal of Irrigation and Drainage. All rights reserved.