Concurrent comparisons of stomatal behavior, water status, and evaporation of maize in soil at high or low water potential

Concurrent measurements of evaporation, leaf conductance, irradiance, leaf water potential, and osmotic potential of maize (Zea mays L. cv. Pa602A) in soil at either high or low soil water potential were compared at several hours on two consecutive days in July. Hourly evaporation, measured on two weighing lysimeters, was similar until 1000 hours Eastern Standard Time, but thereafter evaporation from the maize in the dry soil was always less than that in the wet soil; before noon it was 62% and by midafternoon, only 35% of that in the wet soil. The leaf water potential, measured with a pressure chamber, was between −1.2 and −2.5 bars and between −6.8 and −8 bars at sunrise (about 0530 hours Eastern Standard Time) in the plants in the wet and dry soil, respectively, but decreased quickly to between −8 and −13 bars in the plants in the wet soil and to less than −15 bars in the plants in the dry soil by 1100 to 1230 hours Eastern Standard Time. At this time, the leaf conductance of all leaves was less than 0.1 cm sec⁻¹ in the maize in the dry soil, whereas the conductance was 0.3 to 0.4 cm sec⁻¹ in the leaves near the top of the canopy in the wet soil. The osmotic potential, measured with a vapor pressure osmometer, also decreased during the morning but to a smaller degree than leaf water potential, so that by 1100 to 1230 hours Eastern Standard Time the leaf turgor potential was 1 to 2 bars in all plants. Thereafter, leaf turgor potential increased, particularly in the plants in soil at a high water potential, whereas leaf water potential continued to decrease even in the maize leaves with partly closed stomata. Evidently maize can have values of leaf conductance differing 3- to 4- fold at the same leaf turgor potential, which suggests that stomata do not respond primarily to bulk leaf turgor potential. Evidence for some osmotic adjustment in the plants at low soil water potential is presented. Although the degree of stomatal closure in the maize in dry soil did not prevent further development of stress, it did decrease evaporation in proportion to the decrease in canopy conductance.     

西北黑河中游荒漠绿洲农田作物蒸腾与土壤蒸发区分及作物耗水规律

利用中国生态系统研究网络临泽内陆河流域研究站绿洲农田2009年小气候、湍流交换、土壤蒸发和叶片气孔导度等综合观测试验数据,应用Shuttleworth-Wallace(S-W)双源模型以半小时为步长估算了绿洲农田玉米生长季实际蒸散量,并利用涡动相关与微型蒸渗仪实测数据对田间蒸散发量和棵间土壤蒸发量计算结果进行了检验。结果表明:S-W模型较好地估算研究区的蒸散量,并能有效区分农田作物蒸腾和土壤蒸发;全生育期玉米共耗水640 mm,其中作物蒸腾累积量为467 mm,土壤蒸发累积量为173 mm,分别占总量的72.9%和27.1%;日时间尺度上,作物蒸腾和土壤蒸发分别在0—6.3 mm/d和0—4.3 mm/d之间变化,其日平均分别为2.9和1.0 mm/d;田间供水充足,作物蒸腾与土壤蒸发比值明显受作物生长过程影响,播种—出苗期、出苗—拔节期、拔节—抽雄期、抽雄—灌浆期、灌浆—成熟期,其比值分别为0.04、0.8、7.0、5.2和1.4,不同阶段的比值差异主要受叶面积指数影响。     

覆膜开孔土壤蒸发实验研究

为获得灌后覆膜开孔蒸发过程中土壤含水率分布的动态资料,研制了室内垂直一维入渗-覆膜开孔蒸发动态观测实验系统,并进行了不同覆膜开孔率和不同入渗定额下的覆膜开孔蒸发实验.根据实测资料分析了土表覆膜开孔率和入渗定额不同条件下,蒸发土壤含水率剖面的时间变化和蒸发结束的含水率剖面特征.累积蒸发量随时间变化趋势表明,两者关系符合Gardner理论关系,且该理论关系系数与不同覆膜开孔率和入渗定额存在进一步的函数关系,从而得出覆膜开孔率和入渗定额影响下的累积蒸发量随时间变化多因子模型.同时,采用类似的方法分析了覆膜开孔率和入渗定额对相对累积蒸发量和单位膜孔面积累积蒸发量的影响,得出了定量函数关系,其拟合的相关系数均很高.     

凹凸棒土添加对土壤蒸发及裂缝特征的影响

水分是限制干旱与半干旱地区植被恢复和农业发展的最重要因素之一,减少土壤水分无效蒸发损失可提高水分利用效率。凹凸棒土(ATP)作为一种黏土矿物,其亲水性和吸附性对限制土壤蒸发具有重要作用。本研究选取黄土高原干旱与半干旱区3种不同质地的典型土壤(黑垆土、黄绵土、风沙土),设置5种ATP添加量(0%、1%、2%、3%、4%),使用微型蒸发器在自然条件下进行土壤蒸发试验,探究ATP添加对不同土壤蒸发过程和蒸发面裂缝特征的影响。结果表明: 当ATP添加量<3%时,在同一种土壤下累积蒸发量与蒸发损失率随ATP添加量的增加而减小;ATP添加量为3%时,黑垆土、风沙土的累积蒸发量和蒸发损失率均减小,黄绵土的累积蒸发量和蒸发损失率增加;ATP添加量为4%时,黑垆土的累积蒸发量减小、蒸发损失率增加,风沙土的累积蒸发量增加、蒸发损失率减小,黄绵土的累积蒸发量和蒸发损失率均减小。不同土壤平均累积蒸发量表现为:黑垆土>黄绵土>风沙土。在同一种土壤的整个蒸发过程中,施加ATP处理的土壤含水量始终高于对照。累积蒸发量与时间平方根关系的模拟结果表明,蒸发结束时ATP处理下土壤样品可以释放的水量高于对照。添加ATP后黑垆土和黄绵土的裂缝面密度显著增加,风沙土裂缝面密度随ATP添加量的增加而增加,3种土壤的裂缝面密度在ATP添加量为4%时均达到最大值。ATP添加量为3%时可以在最大程度上减少土壤水分无效蒸发。     

Mercury translocation in and evaporation from soil. III. quantification of evaporation of mercury from podzolized soil profiles treated with Hg Cl

Mercury evaporation from undisturbed iron‐humus podzol lysimeters was measured over 3 months after treatment with HgCl₂ spiked with radioactive ²⁰³Hg. The relative evaporation rate from HgCl₂ treated soils followed the sum of two exponential functions. Because evaporation asymptotically approaches zero with time, the integral of the fit curve represents the evaporative loss in percent of atmospheric deposition. For the soil investigated, about 5% of atmospheric Hg deposition was reemitted into the atmosphere. It is hypothesized that mercury evaporation can decrease the leaching of mercury in and from soil significantly; this effect is probably increasing with decreasing rain acidity or soil acidity. Mercury deposited as soluble salt remains susceptible to reemission to air for 300 d after incorporation into the soil matrix. Indications are found that Hg evaporation from soils in geological background areas predominantly derives from recent atmospheric Hg deposition and not from geological sources.     

半干旱区不同垄沟集雨种植马铃薯模式对土壤蒸发的影响

通过垄沟集雨种植马铃薯试验,研究了不同垄沟集雨种植模式对土壤蒸发的影响.结果表明,在马铃薯全生育期,垄上覆盖塑料薄膜(CR)处理土壤蒸发量为122.9～165 mm,垄上原土夯实不覆膜(UR)处理土壤蒸发量为90.9～101.2 mm,无垄带状种植(CK) 土壤蒸发量为80.7 mm.其中,覆膜垄处理CR₆₀在马铃薯成熟期土壤蒸发强度最大,达2.6 mm·d^-1,平均为1.46 mm·d^-1,而对照的土壤蒸发强度为0.65 mm·d^-1;不覆膜土垄处理(UR₃₀)土壤蒸发强度苗期最小,只有0.2 mm·d^-1,平均为0.39 mm·d^-1,而对照的土壤蒸发强度为0.58 mm·d^-1.在马铃薯生长的现蕾期和开花期,水面蒸发量最大,日平均水面蒸发量分别为8.3和9.0 mm,与土壤蒸发不同步.马铃薯成熟期,各处理棵间土壤蒸发量都达到最大值.覆膜垄蒸发量最大,集雨效果显著,所以应采取抑制土壤蒸发措施,以便进一步提高水分利用效率.     

玉米 线辣椒套作系统中土壤养分与根际土壤微生物、酶活性的关系

采用玉米单作、线辣椒单作、玉米-线辣椒套作3种栽培模式,并在玉米-线辣椒套作的种间根部设3种不同隔离处理（膜隔、网隔和无隔）,研究了玉米-线辣椒套作系统中土壤生物因子与土壤养分的关系．结果表明：玉米-线辣椒套作具有明显优势;与两作物单作和玉米-线辣椒套作种间根区膜隔处理相比,玉米-线辣椒根区无隔和网隔处理复合群体中两作物根际土壤酶活性、微生物数量、土壤养分均显著提高;除有效镁与真菌种群数量、过氧化氢酶活性呈负相关外,其余速效养分与各生物因子均呈显著或极显著正相关．通径分析表明,该系统中促进有机质累积的主要生物因素是脲酶、过氧化氢酶、细菌和蛋白酶,蔗糖酶是影响碱解氮的最主要因子,脲酶是影响有效磷的最主要因子,细菌是影响有效钾的最主要因子,碱性磷酸酶、真菌只是选择性地对有机质的累积和氮、磷、钾有效养分的形成起作用,放线菌对土壤养分的直接作用系数为负,对土壤养分形成的作用较小．     

干旱区滴灌枣棉间作模式下枣树棵间蒸发的变化规律

为明确枣树单、间作棵间土壤蒸发及水分耗散特征。通过大田试验,采用MLS测定枣树单、间作棵间土壤蒸发,并对其土壤蒸发的变化规律和气象因素、土壤因素及边界效应进行试验研究。试验结果表明:枣树棵间土壤蒸发在各生育期均出现不同的差异性。单、间作棵间土壤蒸发量及植株蒸腾量存在显著差异且总体上单作高于间作。对外部影响因素进行研究,枣树棵间土壤蒸发与太阳辐射、土壤含水量等呈现良好的函数关系。但日均温仅与单作棵间土壤蒸发相关性较高,而与间作相关性较差。对间作枣树边界效应进行判别,间作棉花显著影响间作枣树行间棵间土壤蒸发量,且棉花叶面积指数与行间棵间土壤蒸发量呈现良好二次函数关系。该研究在一定程度上体现了间作模式的优势,为其对减少无效水分消耗,提高水分利用效率提供理论依据。     

生物炭对土壤水分蒸发的影响

为确定干旱区生物炭的合理施用量及其对土壤水文过程的影响,采用室内土柱试验,研究了3种生物炭添加量(5%、10%和15%)和4种生物炭类型(d<0.25 mm竹炭、0.25 mm<d<1 mm竹炭、d<0.25 mm木炭和0.25 mm <d<1 mm木炭;d为粒径)对地下水补给、土壤持水能力、土壤水分上升运动和蒸发的影响.结果表明: 生物炭对地下水补给、土壤持水能力、土壤水分上升运动和蒸发都有明显影响,但生物炭原料和粒径不同,其影响效果不同;随生物炭施加量的升高,地下水对土壤补给量增大;添加生物炭可提高土壤持水能力,促进土壤水含量的上升速度,其中,添加竹炭效果大于木炭,小粒径生物炭大于大粒径生物炭;生物炭添加量较低(5%)时能有效抑制土壤蒸发,但添加量过高则可能促进土壤蒸发.干旱地区土壤适当施用生物炭可提高土壤保墒能力.     

几个主要地面因子对草原群落蒸发蒸腾的影响

 在中国科学院内蒙古草原生态系统定位研究站,采用“土柱称重法”,观测了几个主要地面因子对草原群落蒸发蒸腾的影响。主要研究结果如下：1．土壤因子的影响：(1)在通常情况下,草原群落蒸发、蒸腾及蒸散均随土壤水分增加而增大;当土壤水分过多时,群落蒸腾由于植物受涝而降低。(2）在低土壤含水量条件下,群落蒸发随土壤粘粒含量增加呈线性降低;在高土壤含水量条件下,群落蒸发随土壤粘粒含量增加而升高。(3)不同土壤含水量的群落蒸发,均随土壤紧实度增大而升高,并先后达最高值。土壤含水量愈低,蒸发达最高值愈滞后。 2．放牧因素的影响：群落蒸腾与牧压呈线性负相关;群落蒸发与牧压呈线性正相关。群落生物量随牧压增大而降低是导致群落蒸发和蒸腾与牧压呈正、负相关的主要原因。 3．退化群落及其恢复群落的蒸发蒸腾：群落退化导致群落蒸发升高,蒸腾降低;相应的群落恢复导致群落蒸发降低,蒸腾升高。在—定程度上,群落退化及其恢复演替虽然能明显改变群落T／E值1）,但却不会引起群落蒸散值的明显变化。     

Determination and analysis of phreatic water evaporation in extra-arid dune region

Extra-arid desert is a terminal of biological geochemistry circulation system. It has important value in scientific research and huge new discoveries, which is very useful in many regions, such as energy resources, mineral, water resources, ecology, biodiversity, tourism and characteristic agriculture. Meanwhile, extra-arid area’s desertification is a serious threat to the ecological safety of earth. Aeolian desertification is one of style of desertification caused by water shortage. Once desert has formed, it is very difficult to management or recovery. One of most effective methods for desert control is using integrated ecosystem management based on considering water and the soil. Therefore, it is very important to find a new available water resource, and authors’ research is in this field. In this paper, we select a Gobi on Dunhuang Mogao Grottoes of Kumtag desert fringe, where the buried depth of phreatic water is over 200 m. Using an arched shed-air conditioning system, where covered drift sand thickness of 2.0 m, the phreatic evaporation was measured for the first time. In order to analyze influence factors, the evaporation of phreatic water on Gobi was measured and compared. The temperature of soil and air, the humidity inside and outside of the arched shed were also monitored. It is found that the phreatic water under sand can go through sand layer and get to surface, which forms evaporation. The amount of evaporation changes along with solar radiation and temperature fluctuations in the day. It also changes periodically in the year. During five months from June to October, the sunshine time is longer and temperature is higher, and the evaporation is higher too, and the mean daily evaporation is 3.6 g/(m² d). In other periods, the amount of evaporation of phreatic water is extremely weak. It is difficult to monitor by the arched shed-air conditioning system. Compared with Gobi region, the amount of evaporation of phreatic water on dune is very low, which is only 15.0% evaporation on Gobi. The key reason is the difference of salts in soil. The crystal water could be decomposed from salts or combined again. This reversible process plays a key role in transferring phreatic water of dune and Gobi. The amount of phreatic evaporation is proportional to the salts content in shallow soil. The salts content in dune is only 0.7% of salts content in Gobi, and water content in dune is 3.2% of the Gobi soil. According to results of monitoring, the water content is low in sand. The crystal water in shifting sand could be completely decomposed from salts with temperature rising. It causes relative humidity (RH) decreasing, which is inversely in the sand compared to in Gobi soil. In depth of 10 cm sand, the daily fluctuation is about 10%, which is significantly higher than that of in Gobi soil (3%). As the crystalline salt is a kind of typical water carrier, decreasing the content of crystalline salt results to reduce water transporting because carrying capacity of water is significantly reduced. After condensing and collecting 168 days, 9808 g of water was outputted from sand. However, the water content in sand was still obviously higher than original content. That means the underground vapor migrates upward, and the phreatic water moves to surface. From the evaporation comparison of dune and Gobi, we can conclude that the amount of evaporation could be controlled by changing the soil property in interface, this points out the direction for utilization of phreatic water evaporation.     

Estimation of evaporation components in agricultural crops

There are three components of the total evapotranspiration (soil evaporation, interception loss and transpiration) influenced strongly by the vegetation. Hydrological models need information about the temporally varying portions of the components. On a well equipped research station in the east of Germany all these components have been measured under corn, winter wheat and sunflower (Zea mais L., Triticum aestivum L., Helianthus annuus, L.) and calculated with different methods, respectively. The portion of soil evaporation decreased dramatically from 50% at a LAI = 0.5 to 1–5% for dense crops (LAI > 3). It was stated that transpiration and interception loss took place simultaneously.     

土壤呼吸组分分离技术研究进展

分离土壤呼吸组分是理解陆地生态系统碳循环的重要步骤,研究农田生态系统土壤呼吸组分的呼吸过程和机理对促进农业温室气体减排和碳汇增加、气候变化适应、保障粮食安全以及推动农业可持续发展都具有积极意义。本文综述了近年来土壤呼吸组分分离的理论依据、主要技术及分类,系统比较了现有技术优势、劣势和应用领域,并总结了土壤呼吸组分分离技术在国内外农田生态系统中的应用情况。由于多数分离技术在森林生态系统的相关研究中发展而来,它们在农田生态系统的应用十分有限,目前应用以同位素法、根分离法和回归法为主。由于土壤呼吸理论划分和分离方法的差异,不同研究结果之间往往难以比较。分离技术的发展有赖于土壤呼吸源分离理论的进一步发展,未来土壤呼吸组分分离研究的主要方向在于：（1）利用现有观测技术促进组分集成分析法和根分离法在农田生态系统中的应用,强化土壤呼吸组分和环境因子的同步观测,准确评估农田碳收支;（2）利用定位观测数据开展大尺度模型研究,改进和重构现有全球碳模型的碳氮过程,并在其中考虑重要的土壤呼吸过程;（3）利用FACE试验评估气候变化对土壤呼吸组分的影响和土壤-植物碳循环的适应机制;（4）分析呼吸组分与植物-土壤-养分的交互作用,评估农田管理措施的综合影响。     

Effect of rock fragments on the percolation and evaporation of forest soil in Liupan Mountains, China

The water-retaining capacity, percolation and evaporation of stony soil in Liupan Mountains, China, were measured in order to understand the effect of rock fragments on soil hydrological processes. The results indicated that the effective water-retaining capacity of soil is positively related with the volumetric content of rock fragments, but there is no relation between saturated water-retaining capacity and rock fragment content. For the soil layers within 0–40 cm, the steady infiltration rate increases with increasing volumetric content of rock fragments until it reaches the range of 15%–20%, and then it decreases when the rock fragment content further increases. For the soil layers below 40 cm, the steady infiltration rate always increases with increasing rock fragment content. The soil evaporation rate decreases with increasing volumetric content of rock fragments when it varies in the range of 0–20%, while the soil evaporation rate keeps basically stable when the rock fragment content is higher than 20%. The soil evaporation rate shows a rising tendency with increasing size of rock fragments.     

六盘山森林土壤中的砾石对渗透性和蒸发的影响

为了解山地土壤中的砾石对土壤水文循环的影响,测定了砾石土壤的贮水能力、渗透速率和蒸发速率。结果表明,砾石含量与土壤有效贮水量呈正相关关系,但与土壤最大贮水量无明显相关。在0-40cm土层,当砾石体积含量小于15％～20％时,稳渗速率随砾石含量增加而增大,当砾石体积含量大于15％-20％时,土壤稳渗速率随砾石含量增加而减小;在40cm以下土层,稳渗速率随砾石含量增加而提高。在土壤砾石含量为0～20％时,土壤蒸发速率随砾石含量增加而降低,但在砾石含量超过20％时,土壤蒸发速率基本保持稳定。土壤蒸发速率随砾石粒径增大有升高的趋势。     

华北平原农田土壤蒸发δ18O的日变化特征及其影响因素

 土壤蒸发δ¹⁸O (δ_E)是影响大气水汽δ¹⁸O (δ_v)变异的重要因素, 也是农田生态系统蒸散组分土壤蒸发和植物蒸腾拆分的核心科学问题之一。δ_E主要基于Craig-Gordon模型计算, 主要受地表大气水汽δ_v、相对湿度(h)、平衡和动力学分馏系数以及土壤蒸发前缘液态水δ¹⁸O (δ_s)的影响。该研究以华北平原冬小麦(Triticum aestivum)-夏玉米(Zea mays)生态系统大气水汽δ_v的原位连续观测数据为基础, 同时结合不同深度的土壤日变化采样, 综合探讨了δ_E的日变化特征及其影响因素。结果表明: 冬小麦和夏玉米生长季δ_E的日变化表现为双峰曲线, 分别在6:00和15:00左右达到峰值。h强烈影响农田生态系统δ_E, 特别是在h > 95%的高相对湿度环境条件下Craig-Gordon模型并不适用。大气水汽δ_v的原位连续观测技术克服了传统的降水平衡预测大气水汽δ_v方法的不确定性, 可以显著提高δ_E的准确性。不同的平衡分馏系数对δ_E的结果无显著影响。不同的动力分馏系数尤其是考虑湍流扩散对动力分馏系数的影响会显著影响δ_E的模拟结果。土壤蒸发前缘的确定直接影响δ_s和标准化到土壤蒸发前缘温度下的h, 显著影响δ_E的准确性。结合动态箱或静态箱与稳定同位素红外光谱连续观测技术直接测定δ_E, 从而避免模型参数化过程引入的不确定性是未来研究的重要方向。     

荒漠结皮层藓类植物死亡对表层土壤水分蒸发和入渗的影响

水分是荒漠植物生长最主要的限制因子,藓类结皮作为荒漠土壤表层重要覆被物,对土壤水分蒸发入渗具有重要影响。研究表明,在全球气候变化背景下,不确定的降水格局变化导致结皮层藓类植物出现集群死亡现象,但这一过程对荒漠地表土壤水分蒸发与入渗过程的影响及其机理尚不清楚。以古尔班通古特沙漠齿肋赤藓结皮为研究对象,利用便携式渗透计和蒸发仪,研究了结皮层藓类植物死亡对土壤水分蒸发与入渗的影响。结果表明,与裸沙相比,藓类结皮的存在显著抑制了水分入渗,而藓类植物死亡的结皮层抑制作用最大,其初渗速率、稳渗速率和累积入渗量分别是活藓类结皮的39.89%、85.91%及64.48%,仅为裸沙的5.96%、13.13%及20.42%。在水分蒸发初期,裸沙的水分蒸发速率明显高于活藓类结皮和藓类植物死亡的结皮层,但藓类植物死亡的结皮层维持相对稳定的蒸发速率的时间长于裸沙和活藓类结皮,这也导致最终累计蒸发量以藓类植物死亡的结皮层最高、裸沙最低。可见,荒漠生物土壤结皮中藓类植物死亡会明显减少土壤水分入渗、增大水分蒸发,进一步影响荒漠表层土壤水分格局,从而影响生物土壤结皮与维管植物的水分利用关系。     

Effects of straw mulching on soil temperature, evaporation and yield of winter wheat: field experiments on the North China Plain

Straw mulching is an effective measure to conserve soil moisture. However, the existence of straw on the soil surface also affects soil temperature, which in turn influences crop growth, especially of winter crops. Five‐year field experiments (2000–2005) investigated the effects of straw mulching and straw mass on soil temperature, soil evaporation, crop growth and development, yield and water use efficiency (WUE) of winter wheat (Triticum aestivum L.) at Luancheng Station on the North China Plain. Soil is a moderately well‐drained loamy soil with a deep profile at the station. Two quantities of mulch were used: 3000 kg ha^?1 [less mulching (LM)] and 6000 kg ha^?1 [more mulching (MM)], representing half and all of the straw from the previous crop (maize). In the control (CK), the full quantity of mulch was ploughed into the top 20 cm of soil. The results showed that the existence of straw on the soil surface reduced the maximum, but increased the minimum diurnal soil temperature. When soil temperature was decreasing (from November to early February the next year), soil temperature (0–10 cm) under straw mulching was on average 0.3°C higher for LM and 0.58°C higher for MM than that without mulching (CK). During the period when soil temperature increased (from February to early April, the recovery and jointing stages of winter wheat), average daily soil temperature of 0–10 cm was 0.42°C lower for LM and 0.65°C lower for MM than that of CK. With the increase in leaf area index, the effect of mulching on soil temperature gradually disappeared. The lower soil temperature under mulch in spring delayed the development of winter wheat up to 7 days, which on average reduced the final grain yield by 5% for LM and 7% for MM compared with CK over the five seasons. Mulch reduced soil evaporation by 21% under LM and 40% under MM compared with CK, based on daily measuring of microlysimeters. However, because yield was reduced, the overall WUE was not improved by mulch.     

Effect of sand shape on evaporation from soil surface

Summary Loss of water through evaporation for different types of soils was examined. Soils were prepared from a clay soil and multiangular or platy sand in different proportions. The evaporation curves are of the type z=a+bx+cx² but with different slopes. Both soils had the same percentage of clay and sand but platy-sand soils behaved as if they had a finer texture.     

玉米农田蒸散过程及其对气候变化的响应模拟

应用基于生理生态学过程的EALCO模型,对玉米农田生态系统的蒸散(ET)过程进行了模拟,在模型检验基础上,使用该模型模拟了玉米农田生态系统ET过程对未来气候变化的响应。结果表明,EALCO模型中能量与水过程的动态耦合机制使模型能够较好地模拟农田蒸散过程,基于涡度相关法的观测值与模型模拟值在小时、日尺度上均吻合较好,模型可以解释67%的日蒸散的变化特征。对土壤蒸发与冠层蒸腾的分别模拟显示,生长季土壤蒸发约占ET的36%。温度的升高会引起ET与冠层蒸腾的增加,同时土壤蒸发减少;ET对降水减少的响应较为敏感,主要表现在土壤蒸发的下降。大气CO2浓度升高对冠层蒸腾影响显著,该情景下冠层蒸腾下降幅度最大。研究所假设的2100年气候情景下,该农田生态系统生长季蒸散将减少,然而相对于降水的减少而言,蒸散的减少量较小,即水分支出项相对增加,因此,发生土壤水分匮乏的可能性加大,这可能会加剧该地区的暖干化趋势,给作物产量及生态环境带来威胁。