锌肥对干旱下冬小麦产量形成及籽粒锌积累动态的影响

干旱胁迫是造成冬小麦减产的主要原因之一,为探寻干旱防御技术,本研究以豫农211为材料,在拔节期、灌浆期对小麦进行不同水分和锌肥处理,研究了施用锌肥对干旱条件下冬小麦SPAD值、叶片相对含水率、地上部干物质积累、籽粒灌浆速率、籽粒锌积累动态及产量形成的影响。结果表明,干旱胁迫下,冬小麦叶片SPAD值、叶片相对含水率、单株地上部干物质积累、籽粒灌浆速率、籽粒锌积累速率、产量及其构成因素均显著下降,施用适量锌肥可以提高小麦叶片含叶绿素量,增加叶片相对含水率及单株干物质总量,提高籽粒灌浆速率,促进籽粒锌积累速度及最终籽粒含锌量,提高产量。本试验条件下,锌肥能增加干旱下小麦产量4.80%,籽粒含锌量36.86%。     

Effects of deficit irrigation scheduling on yields and soil water balance of irrigated maize

This paper presents the findings of the effect of some selected deficit irrigation scheduling practices on irrigated maize crop in a sub-catchment in south western part of Tanzania. Field experiments, in which maize (TMV1-ST) variety was planted under total irrigation, were conducted during the dry seasons of 2004 and 2005. Surface irrigation method was used and the crop was planted in basins. The seasonal water applied ranged from 400 to 750 mm. Soil moisture content from both cropped and bare soils, leaf area index, dry matter, and grain yields were measured. The dry matter yield ranged between 6,966 and 12,672 kg/ha, and grain yields obtained were between 1,625 and 4,349 kg/ha. The results showed that deficit irrigation at any crop growth stage of the maize crop led to decrease in dry matter and grain yields, seasonal evapotranspiration and deep percolation. Deficit irrigation in any one growth stage of the maize crop only seems to affect grain production and no significant effect on biomass production, but deficit irrigation that spanned across two or more growth stages affect both biomass and grain production drastically. Crop water use efficiency (WUE) and Irrigation water use efficiency (IWUE) were strongly influenced by the number of growth stages in which deficit irrigations were applied and how critical the growth stages were to moisture stress rather than the amount of irrigation water applied. While maximum WUE was obtained under full irrigation, maximum IWUE was obtained in the deficit irrigation treatment at vegetative growth stage, which suggest that IWUE may be improved upon by practicing deficit irrigation at the vegetative growth stage of the maize crop.     

Water use efficiency of narrow row cotton

Summary A field experiment was conducted on the west side of the San Joaquin Valley in California to determine water use, crop growth, yield and water use efficiency of Acala (SJ-2) cotton (Gossypium hirsutum L.) grown in 0.5 m spaced rows on a Panoche clay loam soil (Typic Torriorthents). Evapotranspiration was determined by water balance techniques utilizing neutron soil moisture measurements. All neutron measurements were made within a 3 m soil profile in 0.20 m increments. The measured evapotranspiration was compared to climatic estimates of potential evapotranspiration, and to calculations using a one-dimensional soil water balance model that separately computed soil water evaporation and plant transpiration. Crop growth was determined by weekly destructive plant sampling. Leaf area was determined along with dry matter components of leaves, stems, fruiting parts (flowers and squares) and bolls. Final yield was determined by machine harvesting (brush stripper) 720 m² from each plot. Lint yields and fiber quality were determined by sample ginning and fiber analysis at the U.S. Cotton Research Station at Shafter, California. Three irrigation regimes were established that resulted in an evapotranspiration range from a high deficit condition to full irrigation at the calculated atmospheric demand.The measured evapotranspiration of narrow row cotton under a full irrigation regime was 778 mm, 594 mm under a limited irrigation regime and 441 mm under a regime with no post-plant irrigation. The evapotranspiration from these irrigation treatments was accurately simulated by a water balance model. that used inputs of potential evapotranspiration, leaf area index, soil water holding capacity and root development.The average lint yield from narrow row cotton with a full irrigation regime was 1583 kg/ha, the average lint yield from a limited irrigation regime was 1423 kg/ha and the average lint yield from a treatment with no postplant irrigation (fully recharged soil profile at planting) was 601 kg/ha. The full irrigation regime resulted in a dry matter production of approximately 16 t/ha while the limited irrigated regime produce 11 t/ha and the no-postplant irrigation regime produced 7 t/ha of dry matter. The fiber quality results indicated significant (0.05 level) differences only in 50% span length and micronaire, with the 2.5% span length, uniformity index, elongation and strength indicating no difference.Cotton lint yield was found to be directly related to total evapotranspiration although the relationship was slightly non-linear while dry matter yield was found to be linearly related to evapotranspiration. Both lint and dry matter yield were found to have a linear relationship to estimated transpiration from the water balance model calculations.Contribution from the Unived States Department of Agriculture, Agricultural Research Service, Western Region and the University of California     

Effect of salinity on water stress, growth, and yield of maize and sunflower

Maize and sunflower were grown in tanks filled with loam and clay, and were irrigated with water of three different levels of salinity. Predawn leaf-water potential and stomatal conductance were used as parameters for water stress. The predawn leaf-water potential of maize was higher than that of sunflower, but the effect of salinity and soil texture on the predawn leaf-water potential was the same for both crops. The stomatal conductance of sunflower was much higher and more severely affected by salinity and soil texture than the stomatal conductance of maize.

Although salinity had a more serious effect on the development of leaf area and canopy dry matter of sunflower, its effect on evapotranspiration and grain yield was the same for both crops. Soil texture had a stronger effect on the development of leaf area and canopy dry matter of sunflower, which also appeared in the evapotranspiration and grain yield, indicating that sunflower is more sensitive to drought than maize.     

土壤干旱对小麦茎秆贮藏物质积累与再转运的影响

在防雨池栽条件下,以小麦旱地品种长武134(抗旱性强)和水地品种(抗旱性弱)为试材,研究干旱对不同抗旱性小麦茎秆及其组成节间花后干物质积累、转运及其对籽粒产量贡献率的影响。结果表明,干旱降低了主茎及其各组成节间干物质的积累量、主茎穗粒重积累量及其灌浆中后期的积累速率,长武134(除其它茎)降低幅度均小于陕253;干旱条件下茎秆贮藏物质的转运并未对籽粒产量产生补偿效应,干旱降低主茎穗粒重积累量与其它茎贮藏物质转运量和转运率较低有密切关系;抗旱性强的小麦品种其它茎的转运量、转运率降低幅度均大于抗旱性弱的小麦品种,从而导致其主茎贮藏物质转运对籽粒产量的贡献率显著降低。     

Growth and yield of soybeans under wet soil culture and conventional furrow irrigation in south-eastern Australia

Summary An experiment was conducted to determine the growth and yield responses of two soybean cultivars (Ridley and Sab40) grown on raised beds with continuous water applied in furrows (wet soil culture, WSC), and with conventional furrow irrigation applied at soil water deficits of 35 mm (F) and 70 mm (I). The early growth and leaf area development of both cultivars was reduced by both waterlogging (WSC) and water stress (1) effects compared to the frequently irrigated (F) treatment. Both cultivars acclimated to the WSC conditions and resumed active growth rates comparable to the F treatment. Excessive dry matter accumulation into leaves and stems of Ridley under WSC resulted in severe lodging and significantly reduced grain yield compared to Ridley under F irrigation. The physiological analysis presented showed that under WSC Ridley had a substantially lower light use efficiency compared the F irrigated crop during reproductive growth. It is hypothesised that lodging during this period reduced photosynthate supply as a result of detrimental changes in the pattern of leaf illumination throughout the canopy. The cultivar Sab40 did not lodge under WSC and grain yield was not significantly different from the F irrigated treatment.Further studies on the response of lodging resistant cultivars and different sowing time by plant arrangements to WSC are required to fully assess this technique under commercial conditions. More importantly, studies on soybean production in relation to crop water use and deep drainage losses on a range of soil types are needed to demonstrate that irrigation water applied is used as efficiently as conventional methods.     

Salinity effect on crop development and yield,analysis of salt tolerance according to several classification methods

The publication is a synthesis of previous publications on the results of a long-term lysimeter experiment. From 1989 to 1998, the experimental variables were soil salinity and soil type, from 1999 onwards, soil salinity and crop variety. The plant was studied during the whole growing period by measuring the saline stress and analyzing its effect on leaf area and dry matter development and on crop yield. Salinity affected the pre-dawn leaf water potential, stomatal conductance, evapotranspiration, leaf area and yield.The following criteria were used for crop salt tolerance classification: soil salinity, evapotranspiration deficit, water stress day index. The classification according to soil salinity distinguished the salt tolerant group of sugar beet and wheat, the moderately salt sensitive group comprising broadbean, maize, potato, soybean, sunflower and tomato, and the salt sensitive group of chickpea and lentil. The results for the salt tolerant and the moderately salt sensitive groups correspond with the classification of Maas and Hoffman, excepted for soybean.The evapotranspiration deficit criterion was used, because for certain crops the relation between yield and evapotranspiration remains the same in case of drought and salinity. This criterion, however, did not appear useful for salt tolerance classification.The water stress day index, based on the pre-dawn leaf water potential, distinguished a tolerant group, comprising sugar beet, wheat, maize, sunflower and potato, and a sensitive group, comprising tomato, soybean, broadbean, chickpea and lentil. The classification corresponds with a difference in water use efficiency. The tolerant crops show a more or less constant water use efficiency. The sensitive crops show a decrease of the water use efficiency with increasing salinity, as their yield decreases stronger than the evapotranspiration. No correlation could be found between osmotic adjustment, leaf area and yield reduction. As the flowering period is a sensitive period for grain and fruit formation and the sensitive crops are all of indeterminate flowering, their longer flowering period could be a cause of their greater sensitivity.The tolerant group according to water stress day index can be divided according to soil salinity in a salt tolerant group of sugar beet and wheat and a moderately sensitive group, comprising maize, sunflower and potato. The difference in classification can be attributed to the difference in evaporative demand during the growing period.The sensitive group according to water stress day index can be divided according to soil salinity in a moderately sensitive group, comprising tomato, soybean and broadbean, and a salt sensitive group of chickpea and lentil. The difference in classification can be attributed to the greater salt sensitivity of the symbiosis between rhizobia and grain legume in the case of chickpea and lentil.     

黑河中游春小麦产量与水分利用效率研究

为了确定黑河中游地区的最佳灌溉制度,研究了不同灌溉定额下春小麦的株高、叶面积指数、地上干物质累积量和产量及其构成要素的变化,并对水分利用效率、耗水量和产量进行了相关性分析。结果表明,不同灌溉处理间,春小麦的株高、叶面积指数、干物质累积量在各个生育期的变化速率和增长量有明显差异,且产量及构成要素之间呈现显著性差异。水分利用效率与产量之间呈二次曲线关系。420mm是该地区春小麦的最佳灌溉量。     

The effect of sowing date,irrigation and cultivar on the growth and yield of wheat in the Namoi River Valley,New South Wales

Summary A factorial experiment which examined the effects of sowing date, cultivar and irrigation frequency on the growth and grain yield of irrigated wheat was conducted at Narrabri, New South Wales. Irrigation scheduling was based on morning values of leaf water potentials (_l): plots were watered when _l, had fallen to either –0.8 MPa or –0.4 MPa or were not irrigated during the season.Maximum leaf areas, tiller numbers and total dry matter production were increased by more frequent irrigation, but subsequent tiller death and leaf senescence were generally not reduced by increasing watering. A delay in sowing from 23 June to 23 July reduced yields by 20%, on average. More frequent irrigation increased yields at both sowing dates, but a high protein, locally bred wheat (Songlen) responded less than a cultivar derived from the CIMMYT program (WW 15). The highest yield for Songlen was 570 g m^–2 which was lower than the highest yield for WW 15 (730 g m^–2); both were obtained from the –0.4 MPa treatment sown on 23 June. Compared with irrigated wheat grown in Mexico or southern New South Wales, dry matter production after anthesis at Narrabri was low. It was suggested that high temperatures after anthesis may limit post-anthesis productivity and subsequently, grain yields. The results of this experiment suggested that yields of irrigated wheat in the lower Namoi Valley can be improved through better irrigation management and varietal improvement, but the magnitude of this response may be limited by high spring temperatures.     

基于SIMDual_Kc模型估算非充分灌水条件下冬小麦蒸散量

为研究关中冬小麦植株蒸腾和土壤蒸发规律,利用2 a冬小麦小区控水试验实测数据,率定和验证了双作物系数SIMDual_Kc模型在关中地区的适用性.用大型称重式蒸渗仪的实测蒸散量值(或水量平衡法计算值)与模型模拟值进行对比.结果表明:SIMDualKc模型可较准确地模拟关中不同水分条件下冬小麦蒸散量,且模拟精度较高.模型估算的平均绝对误差为0.643 3 mm/d.模型估算的冬小麦初期、中期和后期的基础作物系数分别为0.35,1.30,0.20.另外,模型还可以较准确地估算不同水分供应条件下的土壤水分胁迫系数、土壤蒸发量和植株蒸散量.冬小麦整个生育期,土壤蒸发主要发生在作物生育前期,中期较低,后期略微增大;植株蒸腾主要发生在作物快速生长期和生长中期,整个生育期中呈先增大后减小的趋势.     

Corn yield and evapotranspiration under simulated drought conditions

Summary Measurements of corn yield and evapotranspiration (ET) were made under a wide variety of limited irrigations simulating drought conditions. Three locations were studied in two seasons. There was a strong linear relation between relative yield and ET (R² = 0.95 for dry matter yield and R² = 0.87 for grain yield) where variable irrigation was applied throughout the season as well as where irrigation was applied only at the early part of the season. Yield predictions using the model PLANTGRO (Hanks, 1974) were made from soil, crop, and climatic data. Agreement between prediction and measurements was better for relative dry matter yield (R² ranged from 0.91 to 0.99) than a relative grain yield (R² ranged from 0.93 to 0.97). The method for predicting grain yields could be improved but a relation involving seasonal estimates of relative transpiration gave good first-order predictions.Contribution from Utah State University Agricultural Experiment Station Journal Paper No 2506     

Water productivity analysis of irrigated crops in Sirsa district,India

Water productivity (WP) expresses the value or benefit derived from the use of water, and includes essential aspects of water management such as production for arid and semi-arid regions. A profound WP analysis was carried out at five selected farmer fields (two for wheat–rice and three for wheat–cotton) in Sirsa district, India during the agricultural year 2001–02. The ecohydrological soil–water–atmosphere–plant (SWAP) model, including detailed crop simulations in combination with field observations, was used to determine the required hydrological variables such as transpiration, evapotranspiration and percolation, and biophysical variables such as dry matter or grain yields. The use of observed soil moisture and salinity profiles was found successful to determine indirectly the soil hydraulic parameters through inverse modelling.Considerable spatial variation in WP values was observed not only for different crops but also for the same crop. For instance, the WP_ET, expressed in terms of crop grain (or seed) yield per unit amount of evapotranspiration, varied from 1.22 to 1.56 kg m⁻³ for wheat among different farmer fields. The corresponding value for cotton varied from 0.09 to 0.31 kg m⁻³. This indicates a considerable variation and scope for improvements in water productivity. The average WP_ET (kg m⁻³) was 1.39 for wheat, 0.94 for rice and 0.23 for cotton, and corresponds to average values for the climatic and growing conditions in Northwest India. Including percolation in the analysis, i.e. crop grain (or seed) yield per unit amount of evapotranspiration plus percolation, resulted in average WP_ETQ (kg m⁻³) values of 1.04 for wheat, 0.84 for rice and 0.21 for cotton. Factors responsible for low WP include the relative high amount of evaporation into evapotranspiration especially for rice, and percolation from field irrigations. Improving agronomic practices such as aerobic rice cultivation and soil mulching will reduce this non-beneficial loss of water through evaporation, and subsequently will improve the WP_ET at field scale. For wheat, the simulated water and salt limited yields were 20–60% higher than measured yields, and suggest substantial nutrition, pest, disease and/or weed stresses. Improved crop management in terms of timely sowing, optimum nutrient supply, and better pest, disease and weed control for wheat will multiply its WP_ET by a factor of 1.5! Moreover, severe water stress was observed on cotton (relative transpiration < 0.65) during the kharif (summer) season, which resulted in 1.4–3.3 times lower water and salt limited yields compared with simulated potential yields. Benefits in terms of increased cotton yields and improved water productivity will be gained by ensuring irrigation supply at cotton fields, especially during the dry years.     

Evapotranspiration,pan evaporation and soil water relationships for wheat (Triticum aestivum)

Controlled irrigation experiments were conducted for wheat grown in lysimeters having undisturbed soil profiles and protected from rainfall with transparent plexiglass roofs. Crop evapotranspiration during different crop growth stages and its relationships with Class A pan evaporation and soil water parameters were studied. The actual evapotranspiration during different crop growth stages was greatly influenced by amount and time of irrigation. The ratio of the maximum evapotranspiration and Class A pan evaporation increased linearly from germination to 46 days after sowing and remained constant at 1.45 from 46 to 76 days. Then the ratio decreased linearly towards the crop ripening. The actual evapotranspiration was equal to the maximum evapotranspiration up to the critical value of relative soil water, and then the actual evapotranspiration decreased at a very fast rate with further decrease in relative soil water. The critical value of the relative soil water varied from 0.65 to 0.84 during the crop growth-stage periods late tillering-heading and dough ripe-ripe, respectively.     

Response of wheat to irrigation with small amounts of water applied in various ways

In dry land agriculture, crop failure is often due to dry seed beds which hamper crop stand establishment and root growth. Irrigation with small amounts of water may make the difference between success and failure of the crop. A 2-year field study on a sandy loam soil evaluated the response of wheat to irrigation with 4—60 mm water applied in various ways. An amount of 4 or 6 mm water applied in the furrow enhanced above-ground plant growth, root growth, grain yield and water use considerably compared to the same amount of water surface applied to seeded rows. With surface irrigation of 40 or 60 mm water, crop growth and grain yield increased further; however, a significantly higher grain yield was obtained with post-seeding rather than pre-seeding irrigation.     

不同产量水平下冬小麦生长发育和耗水特性研究

【目的】通过控制施肥量来模拟冬小麦不同产量水平,进而了解不同产量下冬小麦生长状况及耗水特性变化,为田间用水管理、区域农业高效用水发展战略的制定提供理论依据。【方法】试验设置4个产量水平7 500 kg/hm~2(C0),8 250 kg/hm~2(C5),9 000 kg/hm~2(C10),9 750 kg/hm~2(C15),以不施肥(CK)为对照,研究不同产量下冬小麦叶面积指数、干物质积累、耗水特性及水分利用效率差异变化。【结果】随目标产量的增加,冬小麦叶面积指数、花前及花后干物质累积量、生物量逐渐增加,干物质转移量、干物质转移率和转移干物质对籽粒的贡献率逐渐减少,产量结果基本达到预期目标。与CK相比,C15处理冬小麦叶面积指数、花前及花后干物质累积量、生物量分别平均增加52.6%、25.9%、112.6%、51.2%,而干物质转移量平均减少44.7%,说明冬小麦后期干物质的合成对籽粒高产的形成起主要作用。随目标产量的增加,冬小麦耗水量增加,土壤含水量减少,2016—2017年C0、C5、C10、C15处理冬小麦水分利用效率无显著差异,2017—2018年各处理冬小麦水分利用效率均有显著性差异,与CK相比,C15处理冬小麦耗水量和水分利用效率分别平均增加29.7%、28.5%。【结论】冬小麦随产量提升的叶面积指数、干物质累积量和耗水量显著增加,其中后期干物质的合成是产量形成的主要原因,同时高产条件下冬小麦水分利用效率显著提高。     

寒地黑土区水稻植株干物质积累对耗水过程的响应

为了探究寒地黑土区水稻植株干物质积累对耗水过程的响应规律,于2017年在黑龙江省水稻灌溉试验站的蒸渗仪内进行了水稻耗水试验。采用U7(76)均匀试验设计,深入解析了各生育阶段耗水量对水稻干物质量及干物质积累过程的影响。结果表明,各生育阶段耗水量对水稻干物质积累的影响决定系数由大到小依次为:抽穗开花期、拔节孕穗期与抽穗开花期的耦合效应、拔节孕穗期、抽穗开花期与乳熟期的耦合效应、分蘖中期与抽穗开花期的耦合效应、分蘖中期与拔节孕穗期的耦合效应、分蘖中期。在水稻营养生长阶段,各阶段耗水量通过影响干物质积累进入快速增长的时间和最快增长速率,进而间接影响干物质积累量,分蘖中期耗水量每增加1 mm,将提前0.459 d进入干物质积累快速增长阶段;拔节孕穗期耗水量每增加1 mm,干物质积累的最快增长速率提高0.011 3 g/d。进入生殖生长阶段,各阶段耗水量对干物质积累量的直接影响大于间接影响。各生育阶段耗水量对水稻产量和干物质量的影响排序相同,由大到小依次为:抽穗开花期、拔节孕穗期、分蘖中期、乳熟期、分蘖前期、分蘖后期,拔节孕穗期、抽穗开花期耗水量与水稻经济系数呈显著负相关。研究结果可为寒地黑土区水稻合理制定灌溉制度提供理论依据。     

Validation and testing of the AquaCrop model under full and deficit irrigated wheat production in Iran

Accurate crop development models are important tools in evaluating the effects of water deficits on crop yield or productivity and predicting yields to optimize irrigation under limited available water for enhanced sustainability and profitable production. Food and Agricultural Organization (FAO) of United Nations addresses this need by providing a yield response to water simulation model (AquaCrop) with limited sophistication. The objectives of this study were to evaluate the AquaCrop model for its ability to simulate wheat (Triticum aestivum L.) performance under full and deficit water conditions in a hot dry environment in south of Iran, to study the effect of different scenarios of irrigation (crop growth stages and depth of water applied) on wheat yield. The AquaCrop model was evaluated with experimental data collected during the three field experiments conducted in Ahvaz. The AquaCrop model was able to accurately simulate soil water content of root zone, crop biomass and grain yield, with normalized root mean square error (RMSE) less than 10%. The analysis of irrigation scenarios showed that the highest grain yield could be obtained by applying four irrigations (200 mm) at sowing, tillering, stem elongation and flowering or grain filing stages for wet years, four irrigations (200 mm) at sowing, stem elongation and flowering stages for normal years and six irrigations (300 mm) at sowing, emergence, tillering, stem elongation, flowering and grain filing stages for dry years. The least amount of irrigation water to provide enough water to response to evaporative demand of environment and to obtain high WUE for wet, normal and dry years were 100, 200 and 250 mm, respectively.     

Dry matter,harvest index,grain yield and water use efficiency as affected by water supply in winter wheat

Food production and water use are closely linked processes and, as competition for water intensifies, water must be used more efficiently in food production worldwide. A field experiment with wither wheat (Triticum Aestivum L.), involving six irrigation treatments (from rain-fed to 5 irrigation applications), was maintained in the North China Plain (NCP) for 6 years. The results revealed that dry matter production, grain yield and water use efficiency (WUE) were each curvilinearly related to evapotranspiration (ET). Maximum dry matter at maturity was achieved by irrigating to 94% and maximum grain yield to 84% of seasonal full ET. A positive relationship was found between harvest index (HI) and dry matter mobilization efficiency (DMME) during grain filling. Moderate water deficit during grain filling increased mobilization of assimilate stored in vegetative tissues to grains, resulting in greater grain yield and WUE. Generally, high WUE corresponded with low ET, being highest at about half potential ET. At this location in NCP, highest WUE and grain yield was obtained at seasonal water consumption in the range 250–420 mm. For that, with average seasonal rainfall of 132 mm, irrigation requirements was in the range of 120–300 mm and due to the deep root system of winter wheat and high water-holding capacity of the soil profile, soil moisture depletion of 100–150 mm constituted the greater part of the ET under limited water supply. The results reveal that WUE was maximized when around 35% ET was obtained from soil moisture depletion. For that, seasonal irrigation was around 60–140 mm in an average season.     

Effect of modern irrigation methods on growth and energy production of sweet sorghum (var. Keller) on a dry year in Central Greece

The subject of this project is to estimate the growth and productivity of sweet sorghum [Sorghum bicolor (L.)] var. Keller, under two different irrigation methods – the conventional surface drip method (two treatments) and the subsurface drip method – in a dry year in Central Greece, as an energy crop for the production of bio-ethanol. A field experiment was carried out on the experimental farm of the University of Thessaly during 2005, comprising of a completely randomized block design with four treatments in four blocks, including control (non-irrigated). In the treatments of surface drip method the evapotranspiration needs were satisfied by using full (100% ETm) and supplement (80% ETm) irrigation doses, while in the treatments of subsurface drip method only supplement irrigation water was used (80% ETm) with the aim of more efficient water conservation. Irrigation was fully automated, and application depths were determined, using a class A open evaporation pan for matching the evapotranspiration needs. The growth of the crop was measured by means of plant height and leaf area index, which were determined periodically throughout the growing period. Fresh and dry biomass productions were measured over six harvests covering the entire growth and production process of cultivation. The results of the first year demonstrated a clear superiority of the subsurface drip method on plant heights, leaf area index and total fresh and dry biomass production compared with the surface drip method for equal values of irrigation water. Maximum yield was attained by mid-September, before crop maturation, something which should be taken into consideration when choosing the best harvesting time of the crop. After late September, large negative growth rates were recorded, resulting in an appreciable drop in the final fresh and dry matter yield.     

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。