Effectiveness of Mulching vs. Incorporation of Composted Cattle Manure in Soil Water Conservation for Wheat Based on Eco-Physiological Parameters

Abstract The objective was to study soil water conservation and physiological growth of wheat (Triticum aestivum L.) using composted cattle manure applied either as mulch or incorporated with soil at 20 Mg ha^?1. Haruhikari, a relatively drought‐sensitive and Hongmangmai, a relatively drought‐tolerant wheat, were the cultivars studied under both adequate and deficit irrigation. Fourteen weeks after sowing (WAS), the number of tillers and leaves was significantly reduced by 19 % and 30 % respectively under deficit irrigation and Hongmangmai produced slightly (10 %) more tillers than Haruhikari. Unlike mulching, the incorporation of manure had favourable effects on plants in terms of shoot dry mass (SDM) by 36 % and number of tillers and leaves by 40 %. Haruhikari produced substantially (29 %) greater root mass under adequate irrigation but Hongmangmai produced slightly (2.7 %) more roots and responded much better to manure use whether under adequate or deficit irrigation. As a result, Hongmangmai suffered less severe reductions in tillers and biomass under water stress. In comparison, the mulched manure treatment saved 15 % and 64 % respectively more water than the control and the treatment incorporating manure, but this advantage in water‐saving did not translate to superior plant growth. Leaf water potential (ψ_l) under adequate irrigation significantly exceeded that under deficit irrigation by 27 % and the ψ_l of Haruhikari exceeded that of Hongmangmai by 15 %. However, Hongmangmai may be considered more tolerant of dehydration since it maintained much higher net photosynthetic rates (P_N) even with a lower leaf water potential. The reduction in the P_N and intracellular carbon dioxide concentration (C_i) of the cultivars under deficit irrigation was on account of decreasing stomatal conductance (g_s) and transpiration rate but on average, the g_s of Hongmangmai significantly exceeded that of Haruhikari by as much as 0.53 under adequate irrigation and 0.22 under deficit irrigation. In conclusion, we suggest that the drought tolerance of Hongmangmai was related to its superior root growth and greater ability than Haruhikari, to efficiently utilize incorporated manure for growth under water stress.     

亏缺灌溉下小麦水分利用效率与光合产物积累运转的相关研究

在大田栽培条件下,以小麦旱地品种晋麦47和西峰20、水旱兼用型品种石家庄8号和水地品种4185为材料,分别进行0水(T0)、一水(T1)和二水灌溉(T2)处理(每次灌水量60mm),研究了光合速率、叶面积指数、干物质积累与分配、根系分布、耗水量、产量因子与水分利用效率(WUE)的关系。结果表明,在拔节前不灌溉,拔节到开花期亏缺灌溉,促进干物质积累和深根发育。随着灌溉水的增加,耗水量显著增加,产量和WUE与耗水量呈二次曲线关系。T0处理显著减少了干物质积累和成穗数,产量、经济系数(HI)和WUE最低。T1和T2产量的提高主要是增加了穗数和穗粒数。灌浆期水分亏缺降低了光合速率(Pn)和气孔导度(Gs),加速了功能叶片的衰老,但诱导了花前储存碳库的再转运,显著提高了HI和产量。因此,在拔节和开花期亏缺灌溉促进根系生长,提高了土壤水分的利用效率。而产量和产量WUE的提高主要是由于增加了灌浆期叶片的Pn和光合功能持续期,促进花前储存碳库的再转运,显著提高了HI。     

亏缺灌溉下小麦水分利用效率与光合产物积累运转的相关研究

在大田栽培条件下,以小麦旱地品种晋麦47和西峰20、水旱兼用型品种石家庄8号和水地品种4185为材料,分别进行0水（T0）、一水（T1）和二水灌溉（T2）处理（每次灌水量60 mm）,研究了光合速率、叶面积指数、干物质积累与分配、根系分布、耗水量、产量因子与水分利用效率（WUE）的关系。结果表明,在拔节前不灌溉,拔节到开花期亏缺灌溉,促进干物质积累和深根发育。随着灌溉水的增加,耗水量显著增加,产量和WUE与耗水量呈二次曲线关系。T0处理显著减少了干物质积累和成穗数,产量、经济系数（HI）和WUE最低。T1和T2产量的提高主要是增加了穗数和穗粒数。灌浆期水分亏缺降低了光合速率（P_n）和气孔导度（G_s）,加速了功能叶片的衰老,但诱导了花前储存碳库的再转运,显著提高了HI和产量。因此,在拔节和开花期亏缺灌溉促进根系生长,提高了土壤水分的利用效率。而产量和产量WUE的提高主要是由于增加了灌浆期叶片的P_n和光合功能持续期,促进花前储存碳库的再转运,显著提高了HI。     

Irrigation and Nutrient Effects on Growth and Water–Yield Relationship of Wheat (Triticum aestivum L.) in Central India

Increasing production of wheat from a limited water supply can result from efficient irrigation and nutrient management. A 3‐year field experiment was conducted at the Indian Institute of Soil Science, Bhopal, to study the growth, yield, seasonal evapotranspiration (ET) and water use efficiency (WUE), and the water–yield relationship of wheat in a soybean–wheat cropping system on vertisols. Three levels of irrigation, viz. I₀, no post‐sowing irrigation; I₁, two irrigations [crown root initiation (CRI) and flowering stage]; and I₂, three irrigations (CRI, maximum tillering and flowering stage) and three nutrient management treatments, viz. F₀, control (without fertilizer/manure); F₁, 100 % NPK (100–21.5–24.9 kg ha^?1); and F₂, 100 % NPK + farmyard manure (FYM‐10 t ha^?1) were tested in a split‐plot design with three replication. It has been established (through anova ) that the year effect was rather negligible and the interaction effects of irrigation and nutrient management on the growth parameters, ET, yield components, yield and WUE were significant. Plant height, progressive leaf area index, dry matter accumulation and crop growth rate were higher in I₂F₂, and I₂F₁ and I₁F₂ were statistically at par. The seasonal ET increased significantly with the increase in water supply in every nutrient treatment and it was highest in I₂F₂ and lowest in I₀F₀. The highest grain yield was obtained in I₂F₂; and a similar yield was recorded in I₃F₁ and I₂F₂. This shows a strong interaction effect between irrigation and nutrients. Yield components, viz. number of ears m^?2, number of grains ear^?1 and 1000‐grain weight were significant. The higher number of ears m^?2 containing greater number of grains with relatively heavier weights appeared to have contributed to the higher yield in I₁F₂, I₂F₁ and I₂F₂. The highest WUE obtained in I₀F₂ did not correspond to the highest yield and maximum ET, but a WUE of 10.43 kg ha^?1 mm^?1 in the I₂F₂ combination corresponded with the highest yield and the seasonal ET requirement was 391.8, which was 137 % greater than the water use at maximum WUE. The ET–grain yield relationship was linear, with a lowest regression slope (i.e. marginal WUE) and elasticity of water production (E_wp) in F₀ and a considerably higher slope and E_wp in F₁ and F₂. As the E_wp is positive and close to one in 100 % NPK treatment, the scope of improving WUE and yield with only inorganic fertilizer is very little, and relatively greater scope exists in the integrated management of organic manure and inorganic fertilizer. The results suggest that integrated nutrient management (100 % NPK + FYM) in conjunction with three irrigations maximized yield of wheat with concomitant improvement in ET and WUE under limited water availability.     

不同供水条件下小麦不同绿色器官的气孔特性研究

为了考察小麦叶片与非叶器官气孔结构特性的差异及其对供水条件的反应，本研究设置不同灌水处理，利用电镜观察小麦灌浆期不同绿色器官的气孔分布和结构特征，并分析其与气孔特性指标间的关系。结果表明，在不同灌水处理下看到各非叶器官（穗、旗叶鞘和穗下节间）均分布着气孔，但其数目少于旗叶叶片。护颖仅在远轴面存在气孔；外稃在多水条件下（4水处理）近轴面出现较多气孔，而远轴面看不到气孔，但在水分胁迫（无水处理）条件下，气孔却出现在远轴面而不在近轴面；在不同水分处理下均观察到芒上明显的气孔分布。从气孔大小看，穗各部分（护颖、外稃、内稃和芒）略小于其他器官。随着灌水次数的减少，各器官气孔密度呈增大趋势，气孔器及气孔孔径表现出长度增加、宽度减小的特征。限水灌溉下非叶器官（穗、旗叶鞘和穗下节间）在籽粒灌浆期气孔导度、蒸腾速率和光合速率的稳定性高于叶片。相关分析表明，不同器官的气孔导度与蒸腾速率均呈显著正相关，非叶器官气孔导度与光合速率的相关程度明显低于叶片。说明在干旱少水条件下，叶与非叶器官蒸腾作用均会减弱，叶片光合速率亦相应降低，而非叶器官光合速率可能保持相对稳定，可相对提高其水分利用效率。     

Photosynthetic Response of Wheat to Soil Water Deficits in the Tropics

The changes in photosynthetic rate and translocation of photosynthates in winter wheat (Triticum Aestivum L.) grown in lysimeters were studied, in response to periodic soil water deficit during late tillering and flowering stages. Soil water deficits were imposed to previously nonstressed plants during late tillering and flowering states. Timing of irrigation was scheduled according to the ratio between irrigation water applied and cumulative pan evaporation (IW/CPE) of 0.75 (low deficit), and 0.5 (moderate deficit), as well as by suspending irrigations after crown root initiation stage (severe deficit). To determine the rate of photosynthesis, a short radioactive pulse of ¹⁴CO₂ with 300 ppm concentration was given to second leaf from the top at tillering, and to the flag leaf at flowering stages for 20 second exposure time. The translocation of photosynthates was estimated by scanning ¹⁴C activity in different plant parts. In late tillering the midday Photosynthetic rate (PR) was significantly 3 mg CO₂ dm^?2 h^?1 lower under low water deficit (WD₁) than under zero water deficit (WD₀). Under higher stress conditions, soil water acted as a limiting factor to keep the rate from rising above 13.2 during stress at late tillering (WD₂), 14.5 flowering (WD₄), and 10.0 mg CO₂ dm^?2 h^?1 for stress at both the growth stages (WD₅), respectively. The difference in daily accumulated photosynthesis (8 h), between stressed and nonstressed were 15, 40, 42, and 77 mg CO₂ dm^?2 h^?1 respectively at WD₁ WD₂, WD₄, and WD₅. The retention of ¹⁴C in flag leaf decreased considerably after 24 hours of exposure time when the labelled assimilates were translocated in bulk to the ear head. Under stressed condition a general trend was observed for upward translocation of assimilates towards the ear, even from the stem and root. The percent ¹⁴C activity observed in ear after 24 hours was greatest in severely stressed plants. The photosynthetic rate is reasonable predicted by midday LDR and surface moisture.     

烯效唑干拌种对小麦光合作用和14C同化物分配的影响

研究了烯效唑干拌种对小麦生育后期光合作用及14C同化物分配的调节效应。结果表明,烯效唑处理增加了植株冠层叶面积,处理间差异显著,以20 mg/kg处理的效果最好。与对照相比,旗叶全展后30 d,MDA含量降低了14.3%,可溶性蛋白质和叶绿素含量分别增加了59.4%和12.6%。烯效唑处理提高了小麦旗叶后期光合速率,改变了14C同化物     

Deficit Irrigation of Soya Bean [Glycine max (L.) Merr.] in a Sub-humid Climate

An experiment was conducted to investigate the influence of different levels of water deficit on yield and crop water requirement of soya beans in a sub‐humid environment (Southern Marmara region, Bursa, Turkey) in 2005 and 2006. One full‐irrigated treatment (T₁), one non‐irrigated treatment (T₅) and three different deficit irrigation (T₂ = 25 % water deficit, T₃ = 50 % water deficit, T₄ = 75 % water deficit) treatments were applied to ‘Nova’ soya bean planted on a clay soil. Non‐irrigated and all deficit irrigation treatments significantly reduced biomass and seed yield and yield components. The full‐irrigated (T₁) treatment had the highest yield (3760 kg ha^?1), while the non‐irrigated (T₅) treatment had the lowest yield (2069 kg ha^?1), a 45.0 % seed yield reduction. T₂, T₃ and T₄ deficit irrigation treatments produced 11.7–27.4 % less seed yield than the T₁ treatment. Harvest index showed less and irregular variation among irrigation treatments. Both leaf area per plant and leaf area index were significantly reduced at all growth stages as amount of irrigation water was decreased. Evapotranspiration increased with increased amounts of irrigation water supplied. Our results indicate that higher amounts of irrigation resulted in higher seed yield, whereas water use efficiency and irrigation water use efficiency values decreased when irrigation amount increased.     

小麦叶片水分利用效率及相关生理性状的关系研究

利用19个抗旱性不同的小麦品种,对干旱状态下叶片水分利用效率和光合速率、蒸腾速率等12个指标之间的关系进行了研究。结果表明,叶片水分利用效率与叶片光合速率、蒸腾速率、气孔导度、胞间二氧化碳浓度、水势和叶片离体失水速率之间的关系密切,说明这些生理性状是瞬间和短时期叶片水分利用效率的直接影响因素;而与叶片抗氧化酶活性、蜡质含量、叶片湿度和相对含水量相关性不大。因此认为,应该有针对性地研究与水分利用效率关系密切的生理性状,为小麦抗旱节水遗传育种研究提供理论依据。     

烯效唑浸种对谷子植株生长发育的效应

以晋谷21为试验材料,通过盆栽及根管栽培试验,研究了不同浓度烯效唑(15、30、60和120 mg L^-1)浸种处理对谷子地上和地下农艺性状的影响。结果表明,烯效唑浸种对谷子具有明显的控上促下作用,使谷子根系数量、根系活力、根干重、根系总长度及茎粗与分蘖均明显增加,株高明显降低;此外显著降低了前期谷子叶面积,但后期发生逆转,表现出控前促后的效果;还对开花后谷子植株的衰老具有明显的调节作用,可延长根系活力的缓降期,提高衰老期间根系和旗叶中SOD、POD活性,降低根系与旗叶中MDA含量。烯效唑浸种处理可显著增加谷子的成穗数和千粒重,最终显著增加产量,在本试验条件下以30 mg L^-1烯效唑浸种效果最佳。     

The Physiology and Stability of Leaf Carbon Isotope Discrimination as a Measure of Water‐Use Efficiency in Barley on the Canadian Prairies

Temporal and seasonal water deficit is one of the major factors limiting crop yield on the Canadian prairie. Selection for low carbon isotope discrimination (Δ¹³C) or high water‐use efficiency (WUE) can lead to improved yield in some environments. To understand better the physiology and WUE of barley under drought conditions on the Canadian prairie, 12 barley (Hordeum vulgare L.) genotypes with contrasting levels of leaf Δ¹³C were investigated for performance stability across locations and years in Alberta, Canada. Four of those genotypes (‘CDC Cowboy’, ‘Niobe’, ‘170011’ and ‘Kasota’) were also grown in the greenhouse under well‐watered and water‐deficit conditions to examine genotypic variations in leaf Δ¹³C, WUE, gas exchange parameters and specific leaf area (SLA). The water‐deficit treatment was imposed at the jointing stage for 10 days followed by re‐watering to pre‐deficit level. Genotypic ranking in leaf Δ¹³C was highly consistent, with ‘170011’, ‘CDC Cowboy’ and ‘W89001002003’ being the lowest and ‘Kasota’‘160049’ and ‘H93174006’ being the highest leaf Δ¹³C. Under field and greenhouse (well‐watered) conditions, leaf Δ¹³C was significantly correlated with stomatal conductance (g_s). Water deficit significantly increased WUE, with ‘CDC Cowboy’– a low leaf Δ¹³C genotype with significantly higher WUE and lower percentage decline in assimilation rate (A) and g_s than the other three genotypes (‘Niobe’, ‘170011’ and ‘Kasota’). We conclude that leaf Δ¹³C is a stable trait in the genotypes evaluated. Low leaf Δ¹³C of ‘CDC Cowboy’ was achieved by maintaining a high A and a low g_s, with comparable biomass and grain yield to genotypes showing a high g_s under field conditions; hence, selection for a low leaf Δ¹³C genotype such as ‘CDC Cowboy’ maybe important for maintaining productivity and yield stability under water‐limited conditions on the Canadian prairie.     

灌水时期和灌水量对小麦耗水特性和旗叶光合作用及产量的影响

在2004—2005和2005—2006小麦生长季,以济麦20、泰山23和泰山22为试验材料,研究了不灌水(W0)、拔节水60 mm (W1)、拔节水60 mm+开花水60 mm (W2)和拔节水60 mm+开花水60 mm+灌浆水60 mm (W3) 4个灌水处理条件下小麦耗水特性、旗叶光合作用和产量变化。结果表明,2004—2005生长季,济麦20和泰山23均以W2处理籽粒产量最高,耗水量和灌水效率分别高于和低于W1处理;两品种的水分利用效率均以W1和W2处理高于其他处理,其中济麦20的W1和W2处理无显著差异,而泰山23的W1处理高于W2处理。2005—2006生长季,济麦20和泰山22分别以W1和W2处理获得最高籽粒产量,两处理的耗水量(451.3 mm和459.2 mm)无显著差异;两品种的水分利用效率均以W0处理最高,W3处理最低,其中济麦20的W1处理高于W2处理,而泰山22在两处理间无显著差异。随灌水量的增加,土壤供水量和降水量占总耗水量的百分率降低,灌水量占总耗水量的百分率增大。济麦20的W0处理的旗叶光合速率和磷酸蔗糖合成酶活性在灌浆初期与W1和W2和W3处理无显著差异,灌浆中后期显著降低,但W0处理有利于蔗糖向籽粒转移,灌浆后期旗叶中蔗糖滞留较少,这是W0处理的粒重显著高于其他处理的生理原因之一。综合考虑籽粒产量、水分利用效率和灌水效率,在未灌底墒水条件下,济麦20和泰山23以拔节水灌60 mm或拔节水和开花水各灌60 mm为节水高产的模式;在灌底墒水60 mm条件下,济麦20以拔节水灌60 mm、泰山22以拔节水灌60 mm或拔节水和开花水各灌60 mm为节水高产的模式。     

秋季玉米秸秆覆盖对丘陵旱地小麦生理特性及水分利用效率的影响

西南丘陵冬春季节干旱频繁,严重影响小麦播种立苗及产量。2012—2013(干旱)和2013—2014年度(湿润),在四川简阳开展田间试验,比较不同玉米秸秆处理方式对旱地小麦生理性状、水分利用效率及产量的影响。试验共设4个处理,分别是无覆盖(CK)、无覆盖+播后和拔节期灌水(T1)、休闲期覆盖(T2)和休闲期+小麦生育期覆盖(T3)。干旱年份T1、T2和T3的产量分别为4151、3926和3603 kg hm–2;较CK增产42.0%、34.3%和23.2%,提高水分利用效率27.2%、29.6%和18.8%。湿润年份处理间产量差异较小。与CK相比,干旱年份灌水和覆盖提高了播种至开花阶段的干物质积累量,有效抑制了花后旗叶、倒二叶的叶绿素降解;覆盖处理有利于保持播前充足的底墒及生育期间较高的土壤含水量;T2处理主要生育时期的根干重、根冠比、根长密度、根质量密度和根表面积密度增加,下层土壤中的根系增多。籽粒产量与各生育阶段干物质积累量、花后旗叶和倒二叶的SPAD及水分利用效率呈显著或极显著正相关。秋季玉米秸秆就地覆盖具有显著的纳雨保墒作用,可提高小麦立苗质量,延缓叶片衰老,进而增产。     

水氮耦合对固定道垄作栽培春小麦根长密度和产量的影响

固定道垄作(PRB)是在农田中设固定的机械行走道的一种垄作和沟灌栽培模式,是河西灌区春小麦取代传统平作和大水漫灌种植方式的一种新技术。为了明确PRB种植模式下合理的施氮水平和灌水量,2014—2015年连续2年采用二因素裂区设计,以3种灌溉定额(1200、2400和3600 m3 hm–2)为主区,以4种施氮水平(0、90、180和270kg hm–2)为副区,研究水氮耦合对小麦不同生育期的根长密度及最终产量的影响。随灌水量和施氮量的增加,根长密度呈现先增后降的变化趋势,且灌水量的效应大于施氮水平的效应;开花、灌浆和成熟期的根长密度与籽粒产量呈正相关。回归分析显示,根长密度最大值的水氮耦合条件是灌水量约2850 m3 hm–2、施氮量196~207 kg hm–2。中等灌水量(2400 m3 hm–2)条件下,小麦主要生育期根长密度显著增加,提高了根长密度在40~80 cm土层的分配比例,增加了水分利用效率和氮肥农学利用效率。综合评价小麦籽粒产量、水分利用率和氮肥农学利用效率,中等灌水量与中氮水平(180 kg hm–2)是所有处理中的最佳水氮耦合模式,可用于河西灌区春小麦PRB栽培模式。当加大灌水至3600m3 hm–2时,产量没有显著增加,水分利用效率和氮肥农学利用效率显著下降,其原因可能是高灌水量使小麦主要生育期的根长密度降低,且根长密度在0~40 cm土层的比例升高,在40~80 cm土层的比例下降。     

推迟拔节水及其灌水量对小麦耗水量和耗水来源及农田蒸散量的影响

于2007-2008和2008-2009小麦生长季, 以高产中筋冬小麦品种济麦22为材料, 采用测墒补灌的方法, 研究推迟拔节水及不同灌水水平对冬小麦耗水量、耗水来源、单位土地面积上旗叶叶面积和蒸腾速率、株间蒸发量、籽粒产量及水分利用效率的影响。结果表明, 测墒补灌后0~140 cm土层能够达到目标含水量。相同补灌时期, 随补灌水平的提高, 拔节至开花阶段日耗水量增大, 0~120 cm土层贮水消耗量减小, 生育期总灌水量和田间耗水量增加, 土壤贮水消耗量先增加后减小, 土壤贮水消耗量和降水量占田间耗水量的比例降低。相同补灌水平, 由拔节期推迟至拔节后10 d补灌则麦田日耗水量减小, 挑旗期日耗水量增大, 拔节至开花阶段80~120 cm土层土壤贮水消耗量增加, 生育期总灌水量和田间耗水量亦增加, 降水量、灌水量和土壤贮水消耗量占田间耗水量的比例不变; 灌浆初期单位土地面积上旗叶叶面积和蒸腾速率降低, 株间蒸发量增加; 公顷穗数降低, 穗粒数、千粒重、籽粒产量、水分利用效率和灌水生产效率增加。本试验条件下, 在拔节后10 d补灌至0~140 cm土层平均土壤相对含水量为75%, 开花期补灌至70% (2007-2008年度)是兼顾节水、高产的最优处理。     

不同底墒条件下补灌对冬小麦耗水特性、产量和水分利用效率的影响

我国黄淮平原水资源紧缺,而且年际间降水量及其时间分布存在较大差异,探明不同底墒条件下补充灌溉对冬小麦产量和水分利用效率的调节效应及其生理基础,可为该地区冬小麦节水高产栽培提供理论和技术支持。2013—2014和2014—2015年冬小麦生长季,在播种期0~100 cm土层土壤贮水量分别为201.5(A)、266.3(B)和317.0mm(C)3种底墒条件下,各设置4个补灌水处理,包括不灌水、拔节期+开花期补灌、越冬期+拔节期+开花期补灌、播种期+拔节期+开花期补灌,研究不同处理冬小麦耗水特性、旗叶光合、干物质积累与分配、产量及水分利用效率的差异。结果表明,冬小麦生育期总耗水量和土壤水消耗量均随播种期底墒的提高而增加。在底墒A和B条件下,冬小麦主要消耗降水和灌溉水。提高播种期补灌水平或于越冬期补灌,冬小麦在底墒A条件下对土壤水的消耗量显著增加,在底墒B条件下对土壤水的消耗量显著减少。在底墒C条件下,冬小麦耗水以土壤水为主,其次为降水,再次为灌溉水;播种期或越冬期补灌显著增加生育期总耗水量,对土壤水消耗量则无显著影响。于播种期、拔节期和开花期补灌,冬小麦在底墒A条件下可获得较高的籽粒产量,但水分利用效率较低;在底墒B条件下籽粒产量和水分利用效率均较高;在底墒C条件下,仅于拔节期和开花期补灌即可获得高产和高水分利用效率,播种期和越冬期无需补灌。综上所述,播前底墒是实施冬小麦合理补灌的重要依据。     

灌溉决策方式对冬小麦产量及水分生产效率的影响

为提高小麦水分生产效率,设置了3种灌溉决策方式:Prwin软件决策、彭曼公式决策、经验灌溉(对照),研究其对小麦产量、水分生产效率及相关性状的影响。结果表明:Prwin灌溉决策下,小麦整个生育期灌水2151.0 m3/hm2,比对照节水699.0 m3/hm2,小麦株高、旗叶性状、穗部性状与对照无明显差异,产量达7401.4 kg/hm2,比对照增产7.8%,小麦水分生产效率为1.80 kg/m3,比对照增加26.8%;彭曼公式决策下,比对照节水400.5 m3/hm2,比对照增产4.2%,水分生产效率比对照增加4.1%。     

土壤水分对冬小麦生长后期光能利用及水分利用效率的影响

通过控制不同土壤水分条件形成不同的小麦（Triticum aestivum L.）群体结构,测定了抽穗到成熟期间小麦冠层光合有效辐射（PAR）截获及垂直分布、干物质积累和产量。研究表明,不同处理小麦冠层对PAR的截获量差异较小（小于15.7%）,但冠层上部（60~80 cm）的PAR截获量和生长后期PAR转化效率差异明显（100.7%和63.7%）,与产量和光能利用效率变化一致,可见土壤水分是通过改变小麦群体内PAR垂直分布及PAR转化效率对作物产量和光能利用效率产生影响。抽穗到成熟期间维持小麦冠层上部PAR截获率在50%左右是实现高产的重要保证。随着土壤水分改善,冬小麦光能利用率和产量持续增加,但水分利用效率却先于二者提前降低,说明改善水分利用效率是提高华北地区农业气候资源利用效率的关键。在底墒充足的条件下,分别在拔节和挑旗期灌水60 mm可获得较高的光能和水分利用效率及经济产量     

灌溉和种植模式对冬小麦播前土壤含水量的消耗及水分利用效率的影响

为探讨华北平原地区冬小麦节水栽培的生产措施,2004-2006年,以冬小麦品种8049为试验材料,在大田4种灌溉条件下,研究了等行距平作、宽窄行平作、沟播和垄作4种种植模式对播前土壤含水量消耗及冬小麦耗水量、产量和水分利用效率的影响。结果表明,与等行距平作相比,另3种模式增加了播前土壤含水量的消耗,其耗水量显著提高,尤以沟播模式30 cm以下播前土壤含水量的消耗最为明显。和等行距平作相比,在灌拔节水+抽穗水和灌拔节水+抽穗水+灌浆水条件下,沟播模式显著提高冬小麦产量;而垄作模式的产量没有显著提高。在灌拔节水或灌拔节水+抽穗水条件下,沟播种植模式的水分利用效率显著高于其他3种种植模式。在本试验条件下,沟播种植结合灌拔节水或灌拔节水+抽穗水是一种值得推广的节水种植模式。     

干湿交替灌溉对水稻产量与水分利用效率的影响

本研究旨在阐明干湿交替灌溉影响水稻产量的生理机制。大田种植3个当地高产水稻品种武运粳24 (粳稻)、扬两优6号(两系杂交籼稻)与甬优2640 (三系籼/粳杂交粳稻)。自移栽后7 d设置：常规灌溉(CI,保持水层)和干湿交替灌溉(AWD),观察这2种灌溉模式对水稻根系与地上部生长发育的影响。结果表明,与CI相比,AWD可以显著提高水稻产量与水分利用效率,3个供试品种产量分别提高了5.34%、5.85%和6.62%,水分利用效率分别提高了28.9%、25.3%和27.6%。产量与水分利用效率的提高主要得益于水稻根系和地上部植株的生理功能的改善,表现出灌浆期较高的根系氧化力、根系伤流液强度、根系与叶片中玉米素与玉米素核苷的含量、剑叶净光合速率、籽粒中较高的蔗糖合酶、腺苷二磷酸葡萄糖焦磷酸化酶和淀粉合酶活性、较大的深层(10~20 cm)根系、较高的分蘖成穗率与叶面积指数。