基于Shuttleworth-Wallace模型的科尔沁沙地流动半流动沙丘蒸散发模拟

陆面蒸散发在气候调节和维持区域水量平衡中起关键作用.量化蒸散发及其各组分项,对深刻揭示干旱半干旱地区的生态水文过程具有重要意义.本研究基于科尔沁沙地流动半流动沙丘2017年生长季气象监测系统的原位监测数据,利用Shuttleworth-Wallace(S-W)模型对沙丘蒸散发进行模拟,在此基础上,对蒸散各组分进行拆分,并利用涡度相关对模拟蒸散发值进行验证.结果表明: 整个生长季模型模拟蒸散发值为308 mm,涡度相关实测值为296 mm,偏差较小,证明S-W模型适用于该地区的蒸散发模拟.蒸散发整体呈生长旺盛期>生长后期>生长初期,分别为192、71和45 mm,分别占总量的62.3%、23.1%和14.6%.日尺度上模型模拟值与实测蒸散发值一致性较高,模型模拟精度大体表现为: 晴天>阴天>雨天,且阴雨天模型模拟值较涡度相关实测值偏低.经拆分,土壤蒸发和植被蒸腾分别为176和132 mm,分别占总量的57.1%和42.9%,表明沙地水分利用效率较低.持续干旱和降水后,蒸散发规律明显不同,且土壤蒸发对降水的敏感性强于植被蒸腾.     

Implementing plant hydraulic architecture within the LPJ Dynamic Global Vegetation Model

Aim To implement plant hydraulic architecture within the Lund–Potsdam–Jena Dynamic Global Vegetation Model (LPJ–DGVM), and to test the model against a set of observational data. If the model can reproduce major patterns in vegetation and ecosystem processes, we consider this to be an important linkage between plant physiology and larger‐scale ecosystem dynamics. Location The location is global, geographically distributed. Methods A literature review was carried out to derive model formulations and parameter values for representing the hydraulic characteristics of major global plant functional types (PFTs) in a DGVM. After implementing the corresponding formulations within the LPJ–DGVM, present‐day model output was compared to observational data. Results The model reproduced observed broad‐scale patterns in potential natural vegetation, but it failed to distinguish accurately between different types of grassland and savanna vegetation, possibly related to inadequate model representations of water fluxes in the soil and wildfire effects. Compared to a version of the model using an empirical formulation for calculating plant water supply without considering plant hydraulic architecture, the new formulation improved simulated patterns of vegetation in particular for dry shrublands. Global‐scale simulation results for runoff and actual evapotranspiration (AET) corresponded well to available data. The model also successfully reproduced the magnitude and seasonal cycle of AET for most EUROFLUX forests, while modelled variation in NPP across a large number of sites spanning several biomes showed a strong correlation with estimates from field measurements. Main conclusions The model was generally confirmed by comparison to observational data. The novel model representation of water flow within plants makes it possible to resolve mechanistically the effects of hydraulic differences between plant functional groups on vegetation structure, water cycling, and competition. This may be an advantage when predicting ecosystem responses to nonextant climates, in particular in areas dominated by dry shrubland vegetation.     

千烟洲人工林水汽通量特征及其与环境因子的关系

利用涡度相关技术研究了2004年千烟洲人工针叶林生态系统的水汽通量变化特征,结合气象要素的观测,进一步分析了净辐射、温度、水分、热量等环境因子对水汽通量的影响。结果表明:全年各月各时刻的水汽通量大多为正值,夏季大于春秋两季,冬季最小。其中7月份为全年最高,日最大值达到0·149gm-2·s-1;1月份最低,日最高值仅为0·021gm-2·s-1。不同天气条件下(晴天和多云)水汽通量的日变化有明显区别。全年蒸散量为736·1mm,占总降水量(1323·6mm)的55·6%。除7月份和10月份外,各月的蒸散量都要小于降水,尤以3、4月份差别最大,2004年10月出现典型的秋旱,但蒸散量和常年相差不大。水汽通量对净辐射、气温、地温、以及土壤热通量的变化都有很好的响应,两种天气条件下都能达到显著水平,可以用一元二次方程表达其间的关系。逐步回归分析显示晴天和多云时入选的变量不完全相同,晴天主要是净辐射、温度(气温、地温)、水分(饱和水汽压差),多云时包括净辐射、地温、土壤热通量和水分(空气相对湿度、土壤含水量)。可见气象条件在很大程度上制约着水汽通量的变化,而以辐射和地温的影响最大。     

Studies on water-vapor flux characteristic and the relationship with environmental factors over a planted coniferous forest in Qianyanzhou Station

Water-vapor flux over a planted coniferous forest ecosystem near Qianyanzhou, Jiangxi Province, China, was continuously measured with the eddy covariance technique for 2004. How environmental variables, including net radiation, air temperature, and soil moisture, affected water-vapor flux variation was studied in detail. Results showed that winter had the lowest monthly water-vapor flux value, whereas summer had the highest. The diurnal variation of water-vapor flux showed different patterns for clear and cloudy days. The annual total evapotranspiration was 736.1 mm. Regression analysis showed that daily water-vapor flux was significantly correlated with net radiation, air temperature, soil temperature, and soil heat flux on both clear and cloudy days, all in quadratic relationships. Stepwise regression analysis demonstrated that a different set of environmental factors controlled water-vapor flux on days with different weather conditions. From this study, it was clear that these environmental variables, especially net radiation and soil temperature, regulated water-vapor flux over the planted coniferous ecosystem.     

Soil & Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: A case study in western UK

When considering the large‐scale deployment of bioenergy crops, it is important to understand the implication for ecosystem hydrological processes and the influences of crop type and location. Based on the potential for future land use change (LUC), the 10,280 km² West Wales Water Framework Directive River Basin District (UK) was selected as a typical grassland dominated district, and the Soil & Water Assessment Tool (SWAT) hydrology model with a geographic information systems interface was used to investigate implications for different bioenergy deployment scenarios. The study area was delineated into 855 sub‐basins and 7,108 hydrological response units based on rivers, soil type, land use, and slope. Changes in hydrological components for two bioenergy crops (Miscanthus and short rotation coppice, SRC) planted on 50% (2,192 km²) or 25% (1,096 km²) of existing improved pasture are quantified. Across the study area as a whole, only surface run‐off with SRC planted at the 50% level was significantly impacted, where it was reduced by up to 23% (during April). However, results varied spatially and a comparison of annual means for each sub‐basin and scenario revealed surface run‐off was significantly decreased and baseflow significantly increased (by a maximum of 40%) with both Miscanthus and SRC. Evapotranspiration was significantly increased with SRC (at both planting levels) and water yield was significantly reduced with SRC (at the 50% level) by up to 5%. Effects on streamflow were limited, varying between ?5% and +5% change (compared to baseline) in the majority of sub‐basins. The results suggest that for mesic temperate grasslands, adverse effects from the drying of soil and alterations to streamflow may not arise, and with surface run‐off reduced and baseflow increased, there could, depending on crop location, be potential benefits for flood and erosion mitigation.     

Hydrologic balance,net primary productivity and water use efficiency of the introduced exotic Eucalyptus grandis × Eucalyptus urophylla plantation in south-western China

Aims Land cover changes can disrupt water balance and alter the partitioning of precipitation into surface runoff, evapotranspiration and groundwater recharge. The widely plantedEucalyptustrees in south-western China have the potential to bring about hydrologic impacts. Our research aims to elucidate the hydrologic balance characteristics of the introduced exoticEucalyptus grandis×Eucalyptus urophyllaplantation and to assess whether its high productivity results from high water use efficiency (WUE) or large water consumption.     

地市尺度气候调节服务评估——以福州市为例

生态系统服务是衔接生态系统功能和人类福利的桥梁,气候调节服务在生态系统服务中占有极其重要的地位。对气候调节服务发生的全过程进行评估,对科学开展生态系统服务评估具有重要意义。本研究以福州市为案例,开展地市尺度气候调节服务评估,分析气候调节服务在行政单元、地类尺度上的时空变化特征。结果表明: 2015、2018年,福州市气候调节服务总实物量分别为4.01×10¹² MJ(价值量6139.44亿元,GDP为5618.08亿元)和4.66×10¹² MJ(价值量7140.02亿元,GDP为7856.81亿元),气候调节服务价值大致与当年GDP相当。主要的土地利用/覆被类型是森林、耕地、水域,分别占福州市国土面积的57%、15%和9%;水域对福州市气候调节服务贡献最大,2018年贡献度超过60%,高于林地(12%)及耕地(13%)。建成区、东部农耕区域气候调节服务价值较低。2015、2018年,福州市土地利用/覆被变化面积为1805.5 km²,变化最大的用地类型是耕地、林地,主要的土地利用转移方向是耕地与林地、林地与园地、耕地与城镇村及工矿用地之间的转化;气候调节服务总实物量变化了6.74×10¹¹ MJ,相应的价值变化量为1035.8亿元;气候调节服务变化集中在闽侯、闽清、永泰等中西部地区,以及罗源、福清等西部山区;水域的气候调节服务变化最剧烈,水域类型转化会产生极为强烈的气候调节服务变化,远高于其他用地类型转换的效果。     

淮河流域蒸散发时空变化与归因分析

蒸散发（Evapotranspiration,ET）是联结土壤-植被-大气过程的纽带,对理解地表水热平衡至关重要。因此,量化分析ET时空变化特征、揭示其主要控制因子对区域用水管理和农业生产十分重要。利用遥感数据和气象数据,基于BEPS模型估算了1981-2019年的淮河流域ET,分析了该区域ET时空分布特征,并通过敏感度系数和贡献率方法对该区域的ET多年变化特征进行了归因分析,最后借助数值实验方法深入探究影响特湿润年（2003年）ET较低的主要原因。结果表明：（1）1981-2019年淮河流域多年平均ET为549.83 mm,其中夏季ET占全年ET的比值达到47.63%;1981年以来区域ET整体呈极显著上升趋势（4.41 mm/a,P<0.01）;季节上,除冬季外,其他三个季节的ET增幅均呈显著性增加（P<0.05）,四季增幅速率大小依次为：夏季>春季>秋季>冬季;空间上,中东部和南部ET较高,重心模型显示ET高值区域呈显著的由北向南的移动趋势;（2）归因分析结果表明,淮河流域ET对气温变化最敏感,其次为相对湿度、太阳总辐射、叶面积指数（LAI）和降水,但ET对LAI的正敏感性逐渐增强导致LAI的显著升高对流域ET年际变化贡献最大（44.5%）,其次是气温的升高（25.93%）;同时,LAI是春、夏、秋三季ET变化的主导因素,气温是冬季ET变化的主导因素;（3）数值实验显示高相对湿度是引起特湿润年（2003年）ET明显偏低的最主要因素,这与导致长时间序列ET变化的原因不同。因此,建议今后加强极端气候条件下ET变化的归因分析,为更有效地应对全球气候变化提供决策服务。研究结果能够为认识淮河流域环境变化对水循环影响及合理分配区域水资源提供科学参考。     

近60年秦岭山地旱涝变化规律

随着极端气候变化,山地灾害频发。基于秦岭山地32个气象站点的实测数据,以标准化降水蒸散指数(SPEI)为旱涝量化指标,研究了过去60年秦岭山地旱涝时空变化特征、频率、周期等变化规律,结果表明：(1)1960—2019年,秦岭山地年SPEI指数以0.124/10a的速度下降,其中,90.23%的面积呈显著下降趋势,1.96%的面积呈显著上升趋势,并在1990年发生干旱突变;秦岭北坡的干旱化趋势大于南坡,且高海拔地区干旱化更为明显。(2)突变前秦岭山地湿润比例平均值为36.94%,突变后下降为18.19%;干旱比例由突变前的17.64%急剧上升到突变后的38.19%;突变前30年秦岭山地极端干旱事件、严重干旱事件极少发生,发生频率几乎为0;突变后30年严重干旱和极端干旱事件发生频率增加,秦岭南北坡极端湿润和严重湿润事件近乎销声匿迹。(3)整体上,太阳黑子与秦岭山地旱涝变化以显著负相关关系为主;ENSO事件对秦岭山地的旱涝变化影响较大,在La Nina年易发生洪涝事件,在El Ni1o年易发生干旱事件;在不同时域范围内,海表温度距平(SSTA)对秦岭山地旱涝变化的影响不同：1990年以前,S...