根据作物冠层之上实测温度和湿度廓线确定冠层阻办的一种图解外推法

一、引言对于研究作物冠层显热和潜热输送来说,单层模式(Penman-Monteith方法)仍然被广泛应用,因为它简单易行。在这个方法中,把作物冠层看作是一个面,相当于地面上某一定高度上的一片大叶。类似单叶气孔阻力,Monteith(1963)提出了一个整体阻力r。     

淮北棉区花铃期冠层不同高度叶片光合特性的差异

基于多层二叶模型,在自然群体条件下,将棉花冠层分为上、中、下三层,研究淮北棉花花铃期冠层上、中、下层,阴叶（无直射光照射）与阳叶（有直射光照射）的光合特性的差异。结果表明,同一高度阳叶的光量子通量密度与光合速率显著大于阴叶;不同高度叶片光量子通量密度与光合速率均表现为上层阳叶〉中层阳叶〉下层阳叶,上层阴叶〉中层阴叶〉下层阴叶;上层阳叶气孔导度大于阴叶,中、下层阴、阳叶的气孔导度无显著差异;上部叶片气孔导度〉中部叶片〉下部叶片;同一高度阳叶胞间二氧化碳浓度显著小于阴叶,随着冠层深度（形态学自上而下）的增加,两者差异增大;不同高度叶片胞间二氧化碳浓度随着冠层深度的增加,呈增加趋势,阳叶差异不显著,阴叶差异显著。     

棉花主要生育阶段水分指标

根据田间试验资料,对棉花的气孔阻力进行了分析。结果表明,气孔阻力与土壤湿度呈指数关系。另外,还运用数学方法和最优分割理论,确定了棉花主要生育阶段适宜的土壤水分指标和干旱指标。     

黑河下游影响荒漠河岸胡杨林蒸腾的冠层与大气耦合分析

基于2014年胡杨主要生长季内树形特征、树干液流、环境因子的实际观测数据,利用经验公式,计算了胡杨冠层蒸腾速率、冠层气孔导度与解耦系数的值,分析了其日变化与季节变化特征。结果表明:(1)从日变化趋势来看,解耦系数在早晨和傍晚时较小,中午达到最大值,这主要是由于早晨和傍晚时太阳辐射比较弱、作物气孔开度小,使冠层气孔导度降低造成的;而中午时冠层气孔导度达到全天的最大值,解耦系数值也达到最大。(2)从季节变化趋势来看,解耦系数与冠层气孔导度变化趋势相近,在生长季内均呈先增大后减小,之后略有浮动增大,最后减小的趋势。本研究对影响荒漠河岸胡杨林蒸腾的冠层与下层大气进行相关性推断,认为影响胡杨林蒸腾的冠层与大气耦合度较高。尽管试验地处于极端干旱区,下层大气十分干燥,林冠层叶气界面水分散失很快,但黑河下游河岸林供水良好,林冠层空气动力学条件相近,使得胡杨林蒸腾主要受叶面气孔控制。     

棉花冠层微气象特征研究

利用棉花花铃期作物冠层和农田土壤小气候观测资料分析研究了棉花群体内温度、湿度和风速的时空变化规律,探讨了叶片水势、空气饱和差和冠层净辐射之间的关系,对土壤温度和土壤热通量的变化也进行了客观分析。     

土壤-植被-大气系统水分能量传输模拟和验证

本文建立了包括地下水的土壤－植被－大气系统水分能量传输综合模型,并对模型中冠层动量湍流交换反梯度传输现象的描述进行了改进。在此基础上,依据冠层内动量和热量的交换以及辐射传输过程,同时求解地表、冠层能量平衡方程,进而模拟饱和－非饱和土壤的水热传输。用浅地下水地区冬小麦田间试验资料对模型进行验证,结果表明,系统能量平衡各分量和土壤含水量的模拟与观测结果相当一致。模型敏感性分析发现,叶面积指数对总蒸散量的影响随叶面积指数的增加而逐渐减弱;叶片最小气孔阻力对总蒸散量的影响,在该阻力较小时更显著;地下水位对蒸散量的影响在它小于１．５ｍ时不显著,而在１．５～１．７５ｍ之间时,蒸散减小较快,主要由于土壤蒸发减小显著,冠层蒸腾稍有增加。     

棉花耗水量和土壤水分指标研究

在进行５年的田间试验基础上，从水分利用效率的角度确定了棉花的适宜耗水量指标，根据棉花的蕾铃脱落率，气孔阻力，纤维品质以及产量结构等与土壤湿度的关系，确定了棉花生产的适宜水平指标和干旱指标。     

Penman—Monteith公式中冠层阻抗的合成方法

根据有关学者提出的几种植冠阻抗参数化的代表性理论，由单叶气孔阻抗实测值，结合叶面积垂直分布，资料，提出了３种计算冠层阻抗的合成方法。利用由Ｐ－Ｍ公式反推出的冠层阻抗及由波文比仪测算出的麦田蒸散值对各合成方法进行了效果分析。     

Penman－Monteith公式中冠层阻抗的合成方法

根据有关学者提出的几种植冠阻抗参数化的代表性理论，由单叶气孔阻抗实测值，结合叶面积垂直分布资料，提出了３种计算冠层阻抗的合成方法。利用由Ｐ－Ｍ公式反推出的冠层阻抗及由波文比仪测算出的麦田蒸散值对各合成方法进行了效果分析。     

大气边界层动力学和植被生态过程耦合的一个简单解析理论

发展了一个大气边界层动力学和植被某些生态过程相互作用的简单模式,求得了这个耦合模式的解析解,分析了植被反照率和冠层阻抗(气孔阻力)对大气运动及植被温度的影响,这一相互作用的方式可为进一步发展大气运动和生态过程相互作用的、更复杂的数值模拟模式提供参考.     

Factors affecting the canopy resistance of a Douglas-fir forest

The physiological nature of canopy resistance was studied by comparing the stomatal and canopy resistance of a 10-m high Douglas-fir forest. Stomatal resistance of the needles was measured using porometry, while the canopy resistance was calculated using energy balance/Bowen ratio measurements of evapotranspiration. A typical steady increase in the forest canopy resistance during daytime hours, even at high soil water potentials, was observed. A similar trend in the stomatal resistance indicated that increasing canopy resistance during the daytime was caused by gradually closing stomata. During a dry period when soil water potentials declined from 0 to –10.5 bars, the mean daytime value of canopy resistance increased in proportion to the mean daytime value of the stomatal resistance. Values of canopy resistance calculated from stomatal resistance and leaf area index measurements agreed well with those calculated from energy balance measurements. The dependences of stomatal resistance on light, vapour pressure deficit, twig and soil water potentials art summarized.     

The conductance of a maize crop and the underlying soil to ozone under various environmental conditions

Flux measurements of ozone and water vapour employing the eddy correlation technique were used to determine the surface conductance and canopy conductance to ozone. In the surface conductance to ozone, all surfaces at which ozone is destroyed and the transport process to these surfaces are included. The canopy conductance to ozone represents the ozone uptake of transpiring plant parts. The surface conductance to ozone of the maize crop and the underlying soil was generally larger than the canopy conductance to ozone. This means that beside the uptake by stomata, there was another important ozone sink. Under wet soil surface conditions, the surface conductance and the canopy conductance to ozone coincided. This indicates that the resistance of wet soil and the remaining plant parts (cuticle) to ozone was much larger than the stomatal or soil resistance. On the other hand, under dry soil conditions the conductances differ, largely caused by a variation in the transport process to the soil. The transport of ozone to soil increased with increasing friction velocity (u _*) and decreased with increasing atmospheric stability, leaf area index (LAI) or crop height (h). These effects for midday (unstable) conditions were parameterized with an in-crop aerodynamic resistance,r _inc in a very straightforward way;r _inc=13.9 LAIh/u _*+67 (cc.=0.77). If the ozone flux in air pollution models is described with a simple resistance model (Big Leaf model), the extra destruction at the soil should be modelled using an in-crop aerodynamic resistance. For these measurements the ozone flux to the soil was 0–65% of the total ozone flux measured above the crop. Under wet soil conditions, this was less than 20%; under dry soil conditions, this was 30–65%.     

棉田SPAS水热传输的多层模式

根据能量平衡方程和土壤水热耦合方程，建立土壤－植物－大气系统的多层模式，再综合考虑作物冠层和土壤内部的水热变化，对地表与作物之间的水热传输过程进行了描述，并用棉田的实测资料进行了模拟。     

Evaluation of a Photosynthesis-Based Canopy Resistance Formulation in the Noah Land-Surface Model

Accurately representing complex land-surface processes balancing complexity and realism remains one challenge that the weather modelling community is facing nowadays. In this study, a photosynthesis-based Gas-exchange Evapotranspiration Model (GEM) is integrated into the Noah land-surface model replacing the traditional Jarvis scheme for estimating the canopy resistance and transpiration. Using 18-month simulations from the High Resolution Land Data Assimilation System (HRLDAS), the impact of the photosynthesis-based approach on the simulated canopy resistance, surface heat fluxes, soil moisture, and soil temperature over different vegetation types is evaluated using data from the Atmospheric Radiation Measurement (ARM) site, Oklahoma Mesonet, 2002 International H₂O Project (IHOP_2002), and three Ameriflux sites. Incorporation of GEM into Noah improves the surface energy fluxes as well as the associated diurnal cycle of soil moisture and soil temperature during both wet and dry periods. An analysis of midday, average canopy resistance shows similar day-to-day trends in the model fields as seen in observed patterns. Bias and standard deviation analyses for soil temperature and surface fluxes show that GEM responds somewhat better than the Jarvis scheme, mainly because the Jarvis approach relies on a parametrised minimum canopy resistance and meteorological variables such as air temperature and incident radiation. The analyses suggest that adding a photosynthesis-based transpiration scheme such as GEM improves the ability of the land-data assimilation system to simulate evaporation and transpiration under a range of soil and vegetation conditions.     

棉花耗水规律和灌溉随机控制

根据5年田间试验资料,分析了棉花产量与耗水量的抛物线关系,确定了棉花最佳耗水量;根据棉花植株在不同土壤湿度情况下气孔阻力、蒸腾强度和蕾铃脱落率的变化,确定了不同生育阶段的适宜水分指标和干旱指标。在此基础上,研制了棉花灌溉随机控制模型,可以动态预报棉田土壤有效水分含量和实际蒸散量,并从经济效益和水分利用效率的角度提出优化灌溉决策。     

Evaluating a Model of Evaporation and Transpiration with Observations in a Partially Wet Douglas-Fir Forest

The Penman–Monteith equation is extended to describe evaporation of intercepted rain, transpiration and the interaction between these processes in a single explicit function. This single-layer model simulates the effects of heat exchange, stomatal blocking and changed humidity deficit close to the canopy as a function of canopywater storage. Evaporation depends on the distribution of water over the canopy and the energy exchange between wet and dry parts. Transpiration depends on the dry canopy surface resistance that is described with a Jarvis-type response. The explicit functions obtained for water vapour fluxes facilitate a straightforward identificationof the various processes. Canopy water storage amounts and xylem sapflow were measured simultaneously during drying episodes after rainfall in a dense, partially wet, Douglas-fir forest. Estimates of evaporation and transpiration rates are derived from these observations. The analysis shows that evaporation induced transpirationreduction is mainly caused by energy consumption. Changes in water vapour deficit have a minor effect due to a compensating stomatal reaction. The remaining difference between observed and modelled transpiration reduction can be attributed to partial blocking of stomata by the water layer.     

一个简单的陆面过程模式

本模式为针对大气环流模式所发展的一个简单的陆面过程模式，它包含:（1）地表温度计算，（2）冠层叶面贮水量和土壤湿度计算，（3）陆面与大气之间的水分和能量交换。对于表面温度和含水量的计算，采用的是联立求解计算方案，即耦合计算。植被冠层叶面的辐射特性和冠层形态对冠层中的辐射交换的影响得到有效和尽可能简单的模拟。另外，植被的气孔阻抗、表面与大气之间的水热交换通量和土壤中的水热输导作了较为细致的描写。利用此模式开展了对两个不同覆盖类型的陆面过程的模拟，模拟和观测的表面通量、温度和湿度较为相近。     

Application of transilient turbulent theory to study interactions between the atmospheric boundary layer and forest canopies

The new Forest-Land-Atmosphere ModEl called FLAME is presented. The first-order, nonlocal turbulence closure called transilient turbulence theory (Stull, 1993) is applied to study the interactions between a forested land-surface and the atmospheric boundary layer (ABL). The transilient scheme is used for unequal vertical grid spacing and includes the effects of drag, wake turbulence, and interference to vertical mixing by plant elements. Radiation transfer within the vegetation and the equations for the energy balance at the leaf surface have been taken from Norman (1979). Among others, the model predicts profiles of air temperature, humidity and wind velocity within the ABL, sensible and latent heat fluxes from the soil and the vegetation, the stomata and aerodynamic resistances, as well as profiles of temperature and water content in the soil. Preliminary studies carried out for a cloud free day and idealized initial conditions are presented. The canopy height is 30 m within a vertical domain of 3 km. The model is able to capture some of the effects usually observed within and above forested areas, including the relative wind speed maximum in the trunk space and the counter gradient-fluxes in the lower part of the plant stand. Of special interest is the determination of the location and magnitude of the turbulent mixing between model layers, which permits one to identify the effects of large eddies transporting momentum and scalar quantities into the canopy. A comparison between model simulations and field measurements will be presented in a future paper.