根区交替地下滴灌对马铃薯产量及水分利用效率的影响

采用田间试验方法,研究了根区交替地下滴灌（APRI）对马铃薯生理指标、产量及水分利用效率的影响.结果表明：在马铃薯块茎生长期,与对照处理（CDI）相比,APRI处理的马铃薯叶片光合速率的降低不显著（4.7%）,而蒸腾速率和气孔导度则明显降低,降幅分别达15.8%和15.4%,CDI处理略高的光合速率是以消耗更多的水分为代价;与CDI处理相比,APRI处理的马铃薯产量仅降低5.4%,但灌溉水量却节省了25.8%,使灌溉水分利用效率和总水分利用效率分别提高了27.5%和15.3%.对于马铃薯来说,根区交替地下滴灌是一种切实可行的节水灌溉技术.     

气候变化背景下东北三省主要粮食作物产量潜力及资源利用效率比较

以东北地区喜温作物和喜凉作物的潜在种植区为研究区域,基于研究区域内65个气象台站1961—2010年地面气象观测数据,结合作物生育期资料,应用作物产量潜力逐级订正法,分析不同作物各级产量潜力时空分布特征,明确作物各级产量潜力受气候资源限制程度,比较气候资源利用效率差异.结果表明： 1961—2010年,东北三省6种作物（玉米、水稻、春小麦、高粱、谷子和大豆）的光温产量潜力呈明显的西高东低的空间分布特征,作物气候产量潜力除春小麦外其他作物均呈现南高北低的空间分布规律.6种作物受温度限制的产量潜力损失率呈东高西低的空间分布特征,大豆受温度限制引起的产量潜力损失率最高,平均为51%,其他作物为33%～41%;因降水制约引起的潜力损失率分布有明显的区域性差异,在松嫩平原和长白山区各有一个高值区,春小麦因降水亏缺引起的产量潜力损失率最高,平均为50%,其他4种雨养作物集中在8%～10%.东北三省各作物生长季内光能利用效率在0.9%～2.7%,其中玉米>高粱>水稻>谷子>春小麦>大豆;雨养条件下,玉米、高粱、春小麦、谷子和大豆各作物的降水利用效率在8～35 kg·hm^-2·mm^-1,其中玉米>高粱>春小麦>谷子>大豆.在光能利用效率和降水利用效率均较低的长白山区和小兴安岭南部地区,可采取合理密植、选择适宜品种、适时施肥、蓄水保墒耕作以及优化作物布局等措施提高资源利用效率.     

夏玉米苗期有限水分胁迫拔节期复水的补偿效应

以作物调亏灌溉原理为基础 ,对夏玉米苗期水分胁迫拔节期复水进行了试验研究。结果表明 ,复水增加了夏玉米叶片气孔导度和光合速率 ,提高叶片水平上的水分利用效率(WUE)。复水 2天后 ,叶片气孔导度和光合速率即恢复到对照水平 ,部分时段 ,特别在下午 ,复水处理表现出高于对照的“反冲”现象。复水使苗期受旱的夏玉米株高、叶面积、地上 (下 )部分干物重和根系生长发育都恢复到或接近充分供水的植株生长水平。使其产量及构成因子与对照接近 ,水分利用效率显著地提高了 2 4 7%。这为玉米中后期的水分管理 ,提高玉米水分利用效率 ,提供了一定的理论依据 ;也提供了一种便于广大农民掌握的简单易行的灌溉方式     

不同生育期玉米叶片光合特性及水分利用效率对水分胁迫的响应

利用大型移动防雨棚开展了玉米水分胁迫及复水试验,通过分析玉米叶片光合数据,揭示了不同生育期水分胁迫及复水对玉米光合特性及水分利用效率的影响。结果表明:水分胁迫导致玉米叶片整体光合速率、蒸腾速率和气孔导度下降以及光合速率日变化的峰值提前;水分胁迫后的玉米叶片蒸腾速率、光合速率和气孔导度为适应干旱缺水均较对照显著下降,从而提高了水分利用效率,缩小了与水分充足条件下玉米叶片的水分利用效率差值;在中度和重度水分胁迫条件下,玉米叶片的水分利用效率降幅低于光合速率、蒸腾速率和气孔导度的降幅, 有时甚至高于正常供水条件下的水分利用效率;适度的水分胁迫能提高玉米叶片的水分利用效率,从而增强叶片对水分的利用能力,抵御干旱的逆境;水分亏缺对玉米光合速率、蒸腾速率及水分利用效率的影响具有较明显滞后效应,干旱后复水,光合作用受抑制仍然持续;水分胁迫时间越长、胁迫程度越重,叶片的光合作用越呈不可逆性;拔节-吐丝期水分胁迫对玉米叶片光合作用的逆制比三叶-拔节期更难恢复。     

CO2浓度、氮和水分对春小麦光合、蒸散及水分利用效率的影响

研究了不同土壤氮和土壤水分条件下,大气CO2浓度升高对春小麦光合作用、气孔导度、蒸散和水分利用效率的影响。结果表明,CO2浓度升高,干旱处理的春小麦（Triticum aestivum L.）叶片光合作用速率幅度增加大于湿润处理,随着氮肥用量增加光合速率相应增加,而不施氮脂增加有限;干旱处理气孔导度幅度减少大于湿润处理,不施氮肥的大于氮肥充足的CO2浓度升高,干旱处理的蒸散量减少比湿润处理多,不施氮肥的蒸散量减少较为明显;但干旱处理单叶WUE增加大于湿润处理;随着氮肥用量增加,冠层WUE提高,而不施氮肥的冠层WUE最低。因而CO2浓度升高、光合速率增加和蒸散量减少会减缓干旱的不利影响,增强作物对干旱胁迫的抵御能力。     

春小麦对不同灌水处理的气孔反应及其影响因子

选用3个春小麦品种（系）,采用大田试验方法,在冬灌1800 m³·hm^-2的基础上,在生育期设3次灌水处理（T₁）、2次灌水处理（T₂）和1次灌水处理（T₃）,每次灌水1050 m³·hm^-2,研究土壤水分对春小麦生育期气孔导度的影响及气孔导度与相关环境因素的关系.结果表明：灌水处理对春小麦生育期气孔导度的影响较大,气孔导度随着灌溉次数的减少逐渐降低,同时不同基因型间存在差异.从拔节期到开花期,不同处理春小麦气孔导度变化一致,都呈先升高后降低趋势, 在抽穗期达到峰值;开花期之后各处理出现差异,T₁各品种气孔导度先下降后上升,T₂品种间表现不同,T₃一直呈下降趋势.各环境因子中,大气相对湿度对春小麦气孔导度的影响最大,两者的相关系数在T₂和T₃中分别达显著(0.82^*)和极显著水平(0.92^**).春小麦适应水分亏缺的气孔调节机理为反馈式调节.     

大豆生理生态特性与产量的关系

比较研究了1970s、1980s和1990s期间不同大豆 ( Glycine max (L.) Merr.)品种的生理生态特性:光合作用、蒸腾作用、气孔导度、水分利用效率、胞间CO2浓度和叶片水势,分析了各生理生态特性之间以及与产量在不同生育期的关系.研究表明光合速率和产量之间存在显著的相关关系,高产大豆同时具有高的气孔导度和水势,胞间CO2浓度则很低,特别是在鼓粒期关系更为显著.高产大豆的光合作用在鼓粒期达到最高值,光合作用日变化呈双峰曲线.在鼓粒期高产大豆的光合产物大量运往籽粒中,对于高产品种和高光效-"源"固然重要,而"流"-光合产物的合理运转和分配对产量则更为重要.     

大豆生理生态特性与产量的关系(英文)

比较研究了 1 970s、1 980s和 1 990s期间不同大豆 (Glycinemax (L .)Merr.)品种的生理生态特性 :光合作用、蒸腾作用、气孔导度、水分利用效率、胞间CO2 浓度和叶片水势 ,分析了各生理生态特性之间以及与产量在不同生育期的关系。研究表明光合速率和产量之间存在显著的相关关系 ,高产大豆同时具有高的气孔导度和水势 ,胞间CO2 浓度则很低 ,特别是在鼓粒期关系更为显著。高产大豆的光合作用在鼓粒期达到最高值 ,光合作用日变化呈双峰曲线。在鼓粒期高产大豆的光合产物大量运往籽粒中 ,对于高产品种和高光效_“源”固然重要 ,而“流”_光合产物的合理运转和分配对产量则更为重要     

不同土壤水分条件下无机营养对小麦物质生产和水分利用的影响

本文通过讨论不同土壤水分条件下,无机营养对春小麦净光合率、叶片导度、干物质生产、水分消耗等的影响,表明施肥使营养缺乏的春小麦的光合物质生产,水分消耗及水分利用效率(WUE)都明显增大,无机营养对春小麦物质同化和生长的促进要远大于其因增加水分散失而带来的不利影响;在土壤干旱时,施肥春小麦的光合物质生产、水分消耗下降幅度都大于不施肥春小麦,干旱削弱了无机营养在提高春小麦光合物质生产和产量方面的作用。据此,对旱地的合理施肥技术提出了建议。     

分根区施保水剂对玉米气孔导度和单叶WUE的影响

盆栽条件下,研究了陕单9号玉米(zea mays L．)在根区不施保水剂(对照)、分根区施保水剂和根区全施保水剂3种处理下,叶片气孔导度、CO2吸收和H2O蒸腾的变化。结果表明,在75％土壤饱和持水量下,各指标在3种处理之间没有明显差别;在50％土壤饱和持水量下,分根区施保水剂显著降低了叶片气孔导度,叶片CO2吸收量和H2O蒸腾量也同时降低,但H2O蒸腾量下降幅度更大;在两种水分条件下,分根区施保水剂均能提高玉米单叶水分利用效率(water use efficiency,WUE)。     

Modeling the water use efficiency of soybean and maize plants under environmental stresses: application of a synthetic model of photosynthesis-transpiration based on stomatal behavior

Understanding the variability of plant WUE and its control mechanism can promote the comprehension to the coupling relationship of water and carbon cycle in terrestrial ecosystem, which is the foundation for developing water-carbon coupling cycle model. In this paper, we made clear the differences of net assimilation rate, transpiration rate, and WUE between the two species by comparing the experiment data of soybean (Glycine max Merr.) and maize (Zea mays L.) plants under water and soil nutrient stresses. WUE of maize was about two and a half times more than that of soybean in the same weather conditions. Enhancement of water stresses led to the marked decrease of Am and Em of two species, but water stresses of some degree could improve WUE, and this effect was more obvious for soybean. WUE of the two species changed with psiL in a second-order curve relation, and the WUE at high fertilization was higher than that at low fertilization, this effect was especially obvious for maize. Moreover, according to the synthetic model of photosynthesis-transpiration based on stomatal behavior (SMPTSB) presented by Yu et al. (2001), the WUE model and its applicability were discussed with the data measured in this experiment. The WUE estimated by means of the model accorded well with the measured values. However, this model underestimated the WUE for maize slightly, thus further improvement on the original model was made in this study. Finally, by discussing some physiological factors controlling Am and WUE, we made clear the physiological explanation for differences of the relative contributions of stomata- and mesophyll processes to control of Am and WUE, and the applicability of WUE model between the two species. Because the requirement to stomatal conductance by unit change of net assimilation rate is different, the responses of opening-closing activity of stomata to environmental stresses are different between the two species. To obtain the same level of net assimilation rate, soybean has to open its stomata more widely to keep small stomatal resistance, as compared with maize.     

Experimental Study and Mathematical Simulation of Water Use Efficiency in Wheat Leaves Affected by Some Environmental Factors

By incorporating Ball-Berry model of stomatal conductance into the models of photosynthesis and transpiration, a model of leaf water use efficiency (WUE) as affected by several environmental variables [irradiance (Ⅰ), vapor pressure deficit (VPD) and atmospheric CO2 concentration (Ca) ] was constructed. Because the environmental variables influenced the photosynthetic rate and transpiration rate in different ways, the changes of leaf WUE with these factors were quite complicated. The rates of photosynthesis and transpiration of wheat leaves were also measured in the phytotron where the environmental variables were kept within certain ranges, and leaf WUE was calculated therefrom. The results of simulation fit quite well with the measurements except at high Ca.     

环境因子对小麦叶片水分利用效率影响的实验研究和数值模拟

根据现有的光合作用和蒸腾作用的模型,利用Ｂａｌｌ－Ｂｅｒｒｙ 的气孔导度模型,将叶片的光合作用模型和蒸腾作用模型结合起来,建立了光强（Ｉ）、叶片－大气水汽饱和差（ＶＰＤ）和大气ＣＯ２ 浓度（Ｃａ）等环境因子对小麦叶片水分利用效率（ＷＵＥ）影响的模型。由于这３ 种环境因子对光合、蒸腾的影响方式上的差异,作为两者之比的叶片ＷＵＥ随各环境因子的变化出现复杂的图景,同时,在人工气候箱内分别于这３ 个因子变化时对光合、蒸腾的变化作了测定,计算了叶片的Ｗ ＵＥ。测定结果与模拟结果的对比表明,在多数情况下两者符合程度良好,但在高Ｃａ下有较大的偏离     

全球变化条件下植物个体的生理生态学模型

天气模型中应用随机模拟方法,产生以天或小时为时间间隔的气温、降水、相对湿度、云量、太阳辐射等天气要素的动态变化时间序列。利用北京地区近30年天气资料进行了模拟验证,模拟结果与实际的天气变化进程相符。生理生态模型描述了净光合速率、气孔传导度、蒸腾速率、水分利用效率的变化机理。结合开顶式CO_2浓度倍增大豆(Glycine max(L.)Merr.)生长实验,分析了这些生理生态特性在全球变化下的动态响应机制,并进行了模拟预测。结果表明:CO_2浓度倍增情况下,净光合速率提高45％,其中光量子效率显著增加,而CO_2传导系数略有下降;气孔传导度、蒸腾速率下降约30％;水分利用效率随CO_2浓度增加几乎呈线性增长,倍增后提高近一倍。     

不同基质和生长调节剂对红桂木光合与水分利用效率的影响

利用不同的栽培基质和生长调节剂,探讨其对红桂木光合作用和水分利用效率的影响。结果表明,基质土经改良(S2)并配以适量的吲哚丁酸(IBA)和萘乙酸(NAA),能增强植株的光合速率、蒸腾速率和水分利用率。改良基质(S2)与传统基质(S1)相比,前者显著地促进植株同化物的产生,极显著提高净光合速率、气孔导度、蒸腾速率、水分利用率、叶绿素b含量;IBA+NAA处理与IBA处理、CK相比,前者显著提高净光合速率、水分利用率、总叶绿素、叶绿素a、叶绿素b含量。综合而言,S2-IBA-NAA栽培组合有利于增强红桂木光合作用,提高红桂木同化能力。     

Physiological responses of beech and sessile oak in a natural mixed stand during a dry summer

Responses of CO2 assimilation and stomatal conductance to decreasing leaf water potential, and to environmental factors, were analysed in a mixed natural stand of sessile oak (Quercus petraea ssp. medwediewii) and beech (Fagus svlvatica L.) in Greece during the exceptionally dry summer of 1998. Seasonal courses of leaf water potential were similar for both species, whereas mean net photosynthesis and stomatal conductance were always higher in sessile oak than in beech. The relationship between net photosynthesis and stomatal conductance was strong for both species. Sessile oak had high rates of photosynthesis even under very low leaf water potentials and high air temperatures, whereas the photosynthetic rate of beech decreased at low water potentials. Diurnal patterns were similar in both species but sessile oak had higher rates of CO2 assimilation than beech. Our results indicate that sessile oak is more tolerant of drought than beech, due, in part, to its maintenance of photosynthesis at low water potential.     

Application of a Coupled Photosynthesis–Stomatal Conductance Model to Analysis of Carbon Assimilation by Spruce and Larch Trees in the Forests of Russia

Photosynthetic activities of common spruce (Picea abies (L.) Karst.) and Dahurian larch (Larix gmelinii (Rupr) Rupr ex Kuzen) were analyzed on the basis of datasets obtained for 110- to 130-year-old forest stands in Middle Russia and East Siberia. Using a Li-Cor 6200 gas analyzer, photosynthesis was measured in parallel with transpiration, stomatal conductance, CO₂ concentrations in ambient air and intercellular spaces, the photosynthetically active radiation, air temperature, and air humidity. The data were examined within the framework of a biochemical model of photosynthesis of Farquhar et al. [1] in combination with the stomatal conductance model proposed by Jarvis [2]. The species-specific differences in carbon assimilation rates were discovered, and dependences of photosynthesis on the needle age, light regime, and growth conditions were revealed. The model parameters obtained were used to simulate the photosynthetic rates in spruce and larch trees at various weather conditions.     

Effects of prolonged restriction in water supply on photosynthesis, shoot development and storage root yield in sweet potato

Besides the paucity of information on the effects of drought stress on photosynthesis and yield in sweet potato [ Ipomoea batatas (L.) Lam.], available reports are also contradictory. The aim of this study was to shed light on the effects of long-term restricted water supply on shoot development, photosynthesis and storage root yield in field-grown sweet potato. Experiments were conducted under a rainout shelter where effects of restricted water supply were assessed in two varieties (Resisto and A15). Large decreases in stomatal conductance occurred in both varieties after 5 weeks of treatment. However, continued measurements revealed a large varietal difference in persistence of this response and effects on CO₂ assimilation. Although restricted water supply decreased leaf relative water content similarly in both varieties, the negative effects on stomatal conductance disappeared with time in A15 (indicating high drought acclimation capacity) but not in Resisto, thus leading to inhibition of CO₂ assimilation in Resisto. Chlorophyll a fluorescence measurements, and the relationship between stomatal conductance, intercellular CO₂ concentration and CO₂ assimilation rate, indicated that drought stress inhibited photosynthesis primarily through stomatal closure. Although yield loss was considerably larger in Resisto, it was also reduced by up to 60% in A15, even though photosynthesis, expressed on a leaf area basis, was not inhibited in this variety. In A15 yield loss appears to be closely associated with decreased aboveground biomass accumulation, whereas in Resisto, combined effects on biomass accumulation and photosynthesis per unit leaf area are indicated, suggesting that research aimed at improving drought tolerance in sweet potato should consider both these factors.