三江平原典型沼泽湿地蒸散量研究

利用涡度相关技术对三江平原典型沼泽湿地蒸散量及其影响因子进行研究,结果表明沼泽湿地蒸散量时间变化特征明显。日出后蒸散量逐渐增加,12:00～13:00(北京时间)达到最大值,6～10月各月平均值分别为285.5、257.4、243.0、167.1和65.9W.m-2,各月总蒸散量分别为120.9、101.6、93.1、59.3和25.9mm。与同期降雨量相比,6～9月沼泽湿地水量发生亏缺,亏缺量分别为72.7、3.2、58.8和44.4mm。沼泽湿地蒸散量受环境因子影响强烈。蒸散量与净辐射呈显著线性正相关。蒸散量也随饱和水汽压差的增加而增加,但植物发育成熟后,当饱和水汽压差大于某一阈值(11hPa)时,饱和水汽压差的增加反而抑制了水分蒸散。另外,白天风速增加在一定程度上能够促进水分蒸散。     

基于MODIS遥感产品估算西北半干旱区的陆面蒸散量

在中分辨率成像光谱仪(MODIS)数据产品的基础上,使用MODIS地表温度替代净辐射及蒸散模型中的气温进行计算,并利用兰州大学半干旱气候与环境监测站(SACOL)的实测资料对模型进行修正。将模型修正前后估算的SACOL站和定西干旱气象与生态环境试验站(定西站)的净辐射和蒸散与实测值进行对比。结果表明,MODIS的白天\夜间地表温度与日最高\最低气温之间具有很好的相关性,相关系数都超过0.75,使用其替代气温进行净辐射和蒸散的估算是可行的,且各参数具有明确的物理意义。通过比较模型估算值与地面通量观测站的实测值发现:使用实测资料对模型进行修正后,净辐射和蒸散的估算结果较修正前有了明显的改善。净辐射估算值与实测值之间的均方根误差减小到25.93 W·m~(-2);修正后模型估算的SACOL站和定西站蒸散更接近于实测值,均方根误差分别减小到0.81 mm和0.68 mm,相关系数都增加到0.6以上,通过了0.01显著性水平检验;且遥感估算的区域蒸散分布特征与地表覆盖特征相符,说明利用修正后模型估算的净辐射和地表蒸散是合理的,由于这种估算净辐射和蒸散的模型不需要任何实时地面资料的辅助,可以为观测资料缺乏地区的辐射及蒸散研究提供一种新的思路。     

锦州地区玉米农田生态系统水汽通量变化特征及其调控机制

基于2014年辽宁省锦州地区雨养玉米农田生态系统涡度相关观测数据,分析了锦州地区玉米农田生态系统水汽通量的变化特征,并结合小气候观测数据探讨了水汽通量的调控机制。结果表明:2014年锦州地区玉米农田生态系统各月水汽通量均呈明显的单峰型变化规律,玉米农田生态系统生长季日平均水汽通量可达非生长季的10.31倍。锦州玉米农田生态系统7月水汽通量最大,日最大水汽通量可达0.1202 g·m-2·s-1。玉米农田年蒸散量为417.37 mm,非生长季蒸散总量为49.57 mm,略大于同期降水量;生长季前期5月和6月玉米农田蒸散量占降水量的比例分别为52.0%、71.0%;7月、8月和9月玉米农田的蒸散量大于降水量,其中7月玉米农田的蒸散量为降水量的3.00倍,而此期间正值玉米开花授粉阶段,水分胁迫严重影响玉米产量。玉米农田生长季的水汽通量与净辐射存在显著的正相关关系,同时水汽通量在一定程度上受气温和饱和水汽压差的调控影响。     

基于概念模型的麦田土壤水分动态模拟研究

农田土壤水分模拟是农业用水管理的重要依据。以根区土体水量平衡方程为依据,考虑根区下界面水分通量,构建了农田土壤水分变化模拟模型,该模型由作物蒸散量模型、根区下界面水分通量模型以及水量平衡方程等组成。采用山西水利职业技术学院试验基地2007年和2008年2个年度冬小麦试验资料,确定了模型参数。结果表明,土壤储水量模拟计算值与实测值有较好的一致性,其相关系数达到0.9555;F检验结果达到极显著水平,所建立的麦田土壤水分动态模型可用于作物蒸散量、根区下界面水分通量和田间土壤水分的模拟计算;计算精度平均达到3%～11%。表明该模型可较好地描述农田士壤水分转化过程。     

利用区域气候模式RIEMS产品分析日蒸散量及其影响

利用区域气候模式RIEMS输出的各种气象参数,采用了BEF等4种不同方法计算了沂沭河上游流域的潜在蒸散量,并与该流域6个气象站实测蒸发数据计算的陆面潜在蒸散量进行了比较。结果表明,根据平均偏差、平均绝对偏差、均方根差和相关系数指标的综合判断,该4种方法的估测精度从高到低依次为双线性曲面回归经验函数法(BEF)、Hargreaves-Samani(Harg)法、Pristley-Tayler(P-T)法和Penman-Monteith(P-M)法。在时间序列上,4种方法计算的逐日蒸散量与观测值呈相同的变化趋势,但计算值在蒸散发最强、最弱和降水最多、气温最高的7-9月有较大差异。BEF法估测的精度最高,与观测值最接近,Harg法、P-M法和P-T法都有明显的偏高现象。BEF法只需要较少的参数就能得到较高的估测精度,因此可作为利用区域气候模式RIEMS产品计算沂沭河流域蒸散量的首选方法,进而为RIEMS模式中耦合的陆面水文过程模型TOPX提供满足精度要求的日蒸散量驱动参数。     

大型称重式蒸渗仪测定的冬小麦农田的蒸散规律研究

利用大型称重式蒸渗仪实测数据,对冬小麦蒸散耗水规律进行研究。结果表明：1）冬小麦的目蒸散量变化曲线呈单峰型,中午大,早晚小。蒸散量在分蘖期出现小峰值,此后逐渐降低,返青后又不断增大,在孕穗期土壤水分亏缺严重,作物蒸散量增加速率有所下降。2）Penman—Monteith法估算的实际蒸散量比蒸渗仪实测值略高,怛两者的相关...     

基于Penman-Monteith模型的蒸散模拟评估分析

根据南京地区粳稻、籼稻两个品种水稻分别在干旱、水层条件下的逐时、逐日蒸散量观测资料,采用Penman-Monteith模型(以下简称PM模型)对水稻蒸散量进行模拟,并对比模拟蒸散值与观测蒸散值。通过计算,对PM模型的可靠性进行验证。结果表明:(1)水层条件下PM模型的精度比干旱条件下高。(2)模拟值乘以作物系数后,与蒸散实际测量值更加接近。(3)通过敏感性分析可知,使用PM模型进行蒸散量模拟时,方程中各个因子取值的准确性对模拟结果的精确度有较大影响,计算时要合理确定各个因子值。(4)水层条件下稻田的蒸散量明显大于干旱条件下的蒸散量。     

人工绿地与自然沙地蒸散的计算与变异研究

利用中国气象局塔克拉玛干沙漠气象野外科学试验基地2014—2015年自然沙地与人工绿地加密观测试验时次数据,采用GB/T 20481-2006气象干旱等级的蒸散算法,详细计算自然沙地、人工绿地以时次为单位的蒸散值。计算过程中采用多种参数算法,增加了观测数据的利用率,提高了计算精度,并尝试通过影响因子的变量赋值研究,量化蒸散的计算增减。结果表明:（1）自然沙地与人工绿地蒸散计算值都较好地刻画出了蒸散的年内变化,自然沙地计算值量级更贴近实际观测值,这与蒸散计算方法适用性有关。（2）人工绿地蒸散计算值在植被生长季与观测值的差值较大,自然沙地与观测值的差值较小;冷季人工绿地蒸散计算值与观测值接近,自然沙地计算值与观测值的差相对较大。（3）饱和水汽压与实际水汽压之差、2 m平均气温、2 m平均风速、饱和水汽压的斜率是计算蒸散的主要影响因子,其中饱和水汽压与实际水汽压之差和2 m平均风速随着赋值递增,蒸散差值时次百分比与年累计差值呈线性增长。2 m平均气温随着赋值递增,蒸散差值时次百分比与年累计差值表现比较稳定,饱和水汽压的斜率随着赋值递增,蒸散差值时次百分比与年累计差值略有递减。因此,GB/T 20481-2006气象干旱等级的蒸散算法在塔克拉玛干沙漠的适用性较好,人工绿地比自然沙地计算精度更高。      

作物蒸散的研究:无水分亏缺条件下大豆田间蒸发与蒸腾的分别计算

分别用茎杆热量平衡和鲍思比法来估算无水分亏缺时的大豆田间的蒸腾(T)和蒸散(ET)。从ET中减去T就直接得到了大豆冠层下土壤蒸发的估算值。T/ET比值的日变化可用一条午间值最低、早晨和傍晚值较高的拋物线来表征。这种变化是由冠层吸收太阳直接辐射的日变程而决定的。结果表明,在土壤水分充足的条件下,大豆生育早期冠层稀疏时的田间蒸发,几乎与生育后期冠层稠密时田间的蒸散量相等。冠层下面的土壤日蒸发量随叶面积指数(LAI)增加而非线性下降。将估算蒸散的Makkink太阳辐射模式和冠层太阳总辐射的传输函数结合起来,形成一个估算冠层蒸腾的简单模式。由此模式估算的蒸腾量随叶面积指数的增加而非线性地增大,这种关系可由叶面积指数的负指数函数很好地逼近。     

渍水麦田土壤水分动态模型研究

根据土壤水分平衡原理，建立了一个反映土壤渍水、可与小麦生长模型耦合的土壤水分动态模型，尤其考虑了因地下水位较浅而引起的毛管上升水量和土壤导水率的变化对土壤含水量的影响。采用盆栽小麦水分试验资料验证了日蒸散量的模拟值，利用湖北荆州农业气象试验站和江苏金坛农业气象试验站的土壤水分历史资料对建立的模型进行了综合测试和验证，结果表明:蒸散量、地下水位和0～50 cm土壤含水量的模拟值与实测值具有较好的一致性，模型能可靠地预测多雨和渍水地区麦田土壤水分的变化动态     

Spatial and temporal changes in vapor pressure deficit and their impacts on crop yields in China during 1980–2008

Vapor pressure deficit (VPD) is a widely used measure of atmospheric water demand. It is closely related to crop evapotranspiration and consequently has major impacts on crop growth and yields. Most previous studies have focused on the impacts of temperature, precipitation, and solar radiation on crop yields, but the impact of VPD is poorly understood. Here, we investigated the spatial and temporal changes in VPD and their impacts on yields of major crops in China from 1980 to 2008. The results showed that VPD during the growing period of rice, maize, and soybean increased by more than 0.10 kPa (10 yr)^–1 in northeastern and southeastern China, although it increased the least during the wheat growing period. Increases in VPD had different impacts on yields for different crops and in different regions. Crop yields generally decreased due to increased VPD, except for wheat in southeastern China. Maize yield was sensitive to VPD in more counties than other crops. Soybean was the most sensitive and rice was the least sensitive to VPD among the major crops. In the past three decades, due to the rising trend in VPD, wheat, maize, and soybean yields declined by more than 10.0% in parts of northeastern China and the North China Plain, while rice yields were little affected. For China as a whole, the trend in VPD during 1980–2008 increased rice yields by 1.32%, but reduced wheat, maize, and soybean yields by 6.02%, 3.19%, and 7.07%, respectively. Maize and soybean in the arid and semi-arid regions in northern China were more sensitive to the increase in VPD. These findings highlight that climate change can affect crop growth and yield through increasing VPD, and water-saving technologies and agronomic management need to be strongly encouraged to adapt to ongoing climate change.     

基于温度的参考作物蒸散量计算方法的适用性评价

参考作物蒸散量是表征气候干湿程度、植被耗水量、生产潜力及水资源供需平衡的重要指标之一。以海口和敦煌两个气候相差较大的站点为例,利用Irmark-Allen、Hargreaves、Jensen-Haise 3种基于温度的ET 0计算方法,计算了 2013 2015 年两个站点的参考作物蒸散量,以FAO98 Penman-Monteith方法计算所得结果为标准,依据相关系数(R)及其显著性(P)、均方根误差(RMSE)和平均偏差(MBE)等量化指标,分别对3种方法计算结果在两个站点月和日序列的适用性进行评价,并对这3种方法进行本地化修正优化和检验。结果表明:本地化前,Irmark-Allen方法在海口的计算与Penman-Monteith的偏差最小且相关性好( R =0.97, P <0.01,RMSE=0.38 mm/d,MBE=-0.01 mm/d),其他两种方法均高估。3种基于温度的ET 0方法在敦煌都有很大的误差,其中Irmark-Allen方法在夏季偏低,在冬季偏高;Hargreaves方法整体偏高;Jensen-Haise方法在冬季不适用,出现无效负值,而在其他时段偏高。本地化后,3种基于温度的ET 0方法在两个地区都得到明显改善,其中Jensen-Haise方法在海口效果最好( R =0.96, P< 0.01,RMSE=0.61 mm/d,MBE=0.003 mm/d),在敦煌效果也是最好的( R =0.96, P <0.01,RMSE=0.69 mm/d, MBE=-0.02 mm/d)。     

Error assessment of climate variables for FAO-56 reference evapotranspiration

Meteorological stations, which measure all the required meteorological parameters to estimate reference evapotranspiration (ET_o) using the Food and Agriculture Organization Penman?CMonteith (FAO56-PM) method, are limited in Korea. In this study, alternative methods were applied to estimate these parameters, and the applicability of these methods for ET_o estimation was evaluated by comparison with a complete meteorological dataset collected in 2008 in Korea. Despite differences between the estimation and observation of radiation and wind speed, the comparison of ET_o showed small differences [i.e., mean bias error (MBE) varying ?0.22 to 0.25?mm?day^?1 and root-mean-square-error (RMSE) varying 0.06?C0.50?mm?day^?1]. The estimated vapor pressure differed considerably from the observed, resulting in a larger discrepancy in ET_o (i.e., MBE of ?0.50?mm?day^?1 and RMSE of 0.60?C0.73?mm?day^?1). Estimated ET_o showed different sensitivity to variations of the meteorological parameters??in order of vapor pressure?>?wind speed?>?radiation. It is clear that the FAO56-PM method is applicable for reasonable ET_o estimation at a daily time scale especially in data-limited regions in Korea.     

Regional estimates of evapotranspiration over Northern China using a remote-sensing-based triangle interpolation method

Regional estimates of evapotranspiration (ET) are critical for a wide range of applications. Satellite remote sensing is a promising tool for obtaining reasonable ET spatial distribution data. However, there are at least two major problems that exist in the regional estimation of ET from remote sensing data. One is the conflicting requirements of simple data over a wide region, and accuracy of those data. The second is the lack of regional ET products that cover the entire region of northern China. In this study, we first retrieved the evaporative fraction (EF) by interpolating from the difference of day/night land surface temperature ( T ) and the normalized difference vegetation index (NDVI) triangular-shaped scatter space. Then, ET was generated from EF and land surface meteorological data. The estimated eight-day EF and ET results were validated with 14 eddy covariance (EC) flux measurements in the growing season (July-September) for the year2008 over the study area. The estimated values agreed well with flux tower measurements, and this agreement was highly statistically significant for both EF and ET (p <0.01), with the correlation coefficient for EF (R2 =0.64) being relatively higher than for ET (R2 =0.57). Validation with EC-measured ET showed the mean RMSE and bias were 0.78 mm d-1 (22.03 W m-2 ) and 0.31 mm d-1 (8.86 W m-2 ), respectively. The ET over the study area increased along a clear longitudinal gradient, which was probably controlled by the gradient of precipitation, green vegetation fractions, and the intensity of human activities. The satellite-based estimates adequately captured the spatial and seasonal structure of ET. Overall, our results demonstrate the potential of this simple but practical method for monitoring ET over regions with heterogeneous surface areas.     

Application of a water balance model to estimating hay growth in the peace river region

Abstract

A model that uses daily climate data for calculating hay crop growth in the Peace River region of British Columbia was developed and evaluated using data obtained over four growing seasons. The performances of the ratio of growth to transpiration and the ratio of growth to transpiration (J) divided by vapour pressure deficit (VPD) in estimating crop growth were compared. Transpiration was calculated by subtracting evaporation losses from the soil and foliage from the calculated evapotranspiration. Evapotranspiration was calculated using solar radiation and air temperature, and a one‐layer root zone water balance model, which accounted for soil water supply limitation. Soil water storage measurements showed that the water balance model worked well. The model provided satisfactory estimates of growing season yield of above‐ground dry matter. The use of the ratio of growth toT/ vpd showed no improvement in growth estimation over the ratio of growth to transpiration.     

Agrometeorological study of crop drought vulnerability and avoidance in northeast of Iran

Drought is one of the crucial environmental factors affecting crop production. Synchronizing crop phenology with expected or predicted seasonal soil moisture supply is an effective approach to avoid drought impact. To assess the potential for drought avoidance, this study investigated the long-term climate data of four locations (Bojnourd, Mashhad, Sabzevar, and Torbat Heydarieh) in Khorasan province, in the northeast of Iran, with respect to the four dominant crops (common bean, lentil, peanut, and potato). Weekly water deficit defined as the difference between weekly precipitation and weekly potential evapotranspiration was calculated. Whenever the weekly water deficit was larger than the critical water demand of a crop, the probability for drought was determined. Results showed that Sabzevar has the highest average maximum temperature (24.6 °C), minimum temperature (11.7 °C), weekly evapotranspiration (32.1 mm), and weekly water deficit (28.3 mm) and has the lowest average weekly precipitation (3.8 mm). However, the lowest mean maximum temperature (19.7 °C), minimum temperature (6.9 °C), weekly evapotranspiration (22.5 mm), and weekly water deficit (17.5 mm) occur in Bojnourd. This location shows the shortest period of water deficit during the growing season for all crops except potato, which also experienced drought at the end of the growing season. Sabzevar and Torbat Heydarieh experienced the highest probability of occurrence and longest duration of drought during the growing season for all crops. The result of this study will be helpful for farmers in order to reduce drought impact and enable them to match crop phenology with periods during the growing season when water supply is more abundant.     

Impact of climate change on mid-twenty-first century growing seasons in Africa

Changes in growing seasons for 2041–2060 across Africa are projected using a regional climate model at 90-km resolution, and confidence in the predictions is evaluated. The response is highly regional over West Africa, with decreases in growing season days up to 20% in the western Guinean coast and some regions to the east experiencing 5–10% increases. A longer growing season up to 30% in the central and eastern Sahel is predicted, with shorter seasons in parts of the western Sahel. In East Africa, the short rains (boreal fall) growing season is extended as the Indian Ocean warms, but anomalous mid-tropospheric moisture divergence and a northward shift of Sahel rainfall severely curtails the long rains (boreal spring) season. Enhanced rainfall in January and February increases the growing season in the Congo basin by 5–15% in association with enhanced southwesterly moisture transport from the tropical Atlantic. In Angola and the southern Congo basin, 40–80% reductions in austral spring growing season days are associated with reduced precipitation and increased evapotranspiration. Large simulated reductions in growing season over southeastern Africa are judged to be inaccurate because they occur due to a reduction in rainfall in winter which is over-produced in the model. Only small decreases in the actual growing season are simulated when evapotranspiration increases in the warmer climate. The continent-wide changes in growing season are primarily the result of increased evapotranspiration over the warmed land, changes in the intensity and seasonal cycle of the thermal low, and warming of the Indian Ocean.     

半干旱区不同类型土地利用的蒸散量及水分收支差异分析——以通榆为例

利用吉林通榆半干旱区农田站和退化草地站2008年的外场试验观测资料,对比分析了不同土地利用方式对蒸散和地表水分收支的影响。结果表明：从全年来看,尽管两个站点相距仅5 km,但农田站的全年总蒸散量比代表自然土地覆盖状况的退化草地站高28.2 mm;且生长季两种下垫面的蒸散量较为接近,差异主要发生在非生长季。同时,农田站的年水分收支总量为51.1 mm,比退化草地站低35.6％。具体来说,生长季,两个站点的水分收支均有盈余;但在非生长季,退化草地站的水分收支仍有盈余,而农田站则处于水分亏损状态。这说明在半干旱区,代表人为土地利用状况的农田站面临着更大的水分供给压力,人类活动导致的土地利用会加剧该地区的干旱化趋势。
　　进一步的分析表明,水分盈余并不代表地表的水分状况良好。从 Priestley-Taylor 系数来看,两个站点的Priestley-Taylor系数均远小于1.0,说明在半干旱区,由于表层土壤水分条件的限制,实际蒸散量远未达到平衡蒸散量,土壤面临着水分供给的压力。其可能的原因是,对半干旱区而言,尽管水分收支有盈余,但是由于土壤沙化严重,土壤孔隙度大,大气降水很容易下渗,并以地下水的形式存储起来,使得表层土壤水分供应反而不足。     

Evapotranspiration of deforested areas in central and southwestern Amazonia

Considering the high rates of evapotranspiration of Amazonian forests, understanding the impacts of deforestation on water loss rates is important for assessing those impacts on a regional and global scale. This paper quantifies evapotranspiration rates in two different pasture sites in Amazonia and evaluates the differences between the sites. In both places, measured evapotranspiration varies seasonally, decreasing during the dry season. The decrease is higher at the southwestern Amazonia site, while at the central Amazonia site, the decrease is less pronounced. During the dry season, average values of evapotranspiration are around 2.2?±?0.6?mm?day^?1 in central Amazonia and 2.4?±?0.6?mm?day^?1 in southwestern Amazonia, while during the wet season, those values are 2.1?±?0.6?mm?day^?1 in central Amazonia and 3.5?±?0.8?mm?day^?1 in southwestern Amazonia. On an annual basis, the pasture in southwestern Amazonia has higher evapotranspiration than in central Amazonia. We conclude that the main reason for this difference is the lower available energy in the wet season at the central Amazonian site, combined with a lower leaf area index at this site during the whole year. Still, the evapotranspiration is significantly controlled by the vegetation, which is well coupled with the local moisture conditions in the dry season.     

Surface energy- and water balance in a high-arcticenvironment in NE Greenland

Summary  Within the framework of the European LAPP-project (Land Arctic Physical Processes) and as part of the Danish Research Council’s Polar Programme, studies on water- and surface energy balance in NE Greenland were conducted in 1996 and 1997. Eddy correlation measurements of water vapour and sensible heat fluxes above the three dominant vegetation types: fen, willow snowbed, and heath were conducted for the entire growing season. This was supplemented by measurements of evaporation from snow covered areas and from a small pond. The evapotranspiration was found to be relatively high with the maximum from the fen (≈86 mm per season). For the two other vegetation types the evapotranspiration was less, for heath 61 mm per season, while willow snowbed had evaporation rates on intermediate level. By use of the Penman-Monteith equation it was possible to estimate the altitude dependence of the evapotranspiration and calculate the annual evaporation for the whole area to 80 mm per year. By applying a bucket model the evaporation was found to be in accordance with changes in soil moisture as monitored with TDR. The observed surface water balance was compared to river discharge, which shows a glacio-nival regime with an early spring flow (June), determined by the snow melt in the main valley and an July–August maximum determined by melt on higher plateau areas. When balancing the individual hydrological components an annual deficit of 180 mm was observed, but it was found that this deficit could be reduced by correcting for aerodynamic and altitude effects on the precipitation. Finally some of the possible consequences of a global warming is discussed in relation to the water and energy balance in the high-arctic ecosystem. Received November 1, 1999 Revised May 15, 2000