西北干旱区夏季大气边界层结构及其陆面过程特征

在中国西北干旱区影响大气边界层形成和发展的气候环境和大气环流背景都具有一定特殊性.文中用外场观测试验资料,分析了位于西北干旱区的敦煌荒漠夏季大气边界层气象要素结构特征,发现该地区无论白天的对流边界层还是夜间的稳定边界层均比一般地区更深厚.在夏季晴天,夜间稳定边界层厚度超过900 m,最厚可以达到1750 m,其上的残余层一般能达到4000 m左右的高度;白天混合层最高达3700 m,混合层顶的逆温层顶盖的厚度大约450 m,甚至更厚,对流边界层厚度能够超过4000 m,对流边界层进入残余层后发展十分迅速.研究表明,白天深厚的对流边界层是夜间保持清晰而深厚的残余混合层的先决条件,夜间深厚的残余混合层又为白天对流边界层的发展提供了一个非常有利的热力环境条件.该地区经常性出现连续性晴天使得大气残余层的累积效应得以较长时间持续发展,创造了比较有利于大气对流边界层发展的大气热力环境条件.同时,该地区陆面过程和近地层大气运动特征也为这种独特的大气热力边界层结构提供了较好的支持.就该地区发展超厚大气对流边界层的物理机理而言,地表显著增温是强有力的外部热力强迫条件,近地层强感热通量提供了较充足的能量条件,较大的对流运动和湍流运动的速度是必要的运动学条件,大气残余层的累积效应提供了有利的热力环境条件.     

西北干旱区夏季晴天、阴天边界层结构及其陆面过程对比分析

以2006年夏季敦煌野外观测的探空资料为基础,对比研究了西北的荒漠区晴天、阴天大气边界层的构造以及对应的陆面过程。结果表明,西北荒漠区晴天和阴天的对流边界层以及稳定边界层均比中国中部、东部地方发展旺盛。相比而言,晴天的边界层在构造和陆面过程都和阴天存有较大差异。晴天对流边界层高度可达3.5 km,稳定边界层高度约为1 km,而阴天这两者的日最大高度分别仅约为2.5km和0.2 km。除边界层高度外,西北荒漠区的比湿表现为阴天高于晴天,晴天比湿随高度变化幅度大于阴天,阴天从地表开始向上200 m内出现较弱的逆湿现象,而晴天不出现逆湿现象。造成晴天、阴天边界层的不同原因主要是热力因子和动力因子差异。首先,强烈的太阳辐射、较大的感热通量转化率使得晴天比阴天热对流发展更加旺盛;其次,近地面水平风速晴天的速度均比阴天大,这种以湍流形式的动力作用也为晴天边界层的发展高度大于阴天提供了一定的动力背景。对流边界层在发展初期受陆面热力因子影响很大,没有了稳定边界层的限制后就会迅速发展,而且发展在时间上与净辐射、地表温度、感热通量的日变化中表现出一定的滞后性,这与能量的转化和传输有关。     

风切变对边界层对流影响的大涡模拟研究

利用"西北干旱区陆-气相互作用野外观测实验"加密观测期间在敦煌站的观测资料以及大涡模式,模拟了对流边界层的发展,以及示踪物从混合层向残留层传输的时空变化。模拟的对流边界层的结构及演变特征与实测结果基本一致。进一步通过有风切变和无风切变的敏感性数值试验,研究了风切变对垂直速度、位温和示踪物浓度的水平分布以及示踪物传输高度的影响。研究结果表明,在有风切变的试验中(甚至风切变仅存在于近地层中),对流边界层的增长加强,而且示踪物被传输的高度也较高。与浮力驱动的对流边界层相比,由浮力和风切变共同驱动的边界层中上升气流较弱而下沉气流较强,但前者的上升气流与下沉气流的分布在垂直方向上更为倾斜。由于夹卷作用的增强,浮力和风切变共同驱动的对流边界层较浮力驱动的对流边界层暖。在夹卷层,浮力和风切变共同驱动的边界层对流的上升气流和下沉气流都比浮力驱动的边界层对流中的强,而且垂直速度的概率密度函数分布也较对称,其位温和示踪物浓度的概率密度函数分布也比浮力驱动的边界层中的平直。对湍流动能收支的分析也表明风切变对湍流动能有重要影响,尤其对夹卷层中的湍流动能切变产生项影响较大。示踪物浓度的概率密度函数垂直分布显示,浮力驱动的边界层中示踪物浓度随高度变化较小,而浮力和风切变共同驱动的边界层中示踪物浓度随高度递减,但是示踪物传输的高度比较高。     

一次干冷空气过境对鄂陵湖地区大气边界层过程的影响

利用2012年夏季黄河源区鄂陵湖的GPS探空资料,分析了一次干冷空气过境前后该地区大气边界层位温、比湿和风速风向的垂直分布及其与地表热力作用的关系。结果表明,冷空气过境前的晴天时,湖区白天对流边界层高度不足100 m,远小于陆地,而夜间可以达到400~600 m;伴随着冷空气的到来,湖区对流边界层迅速增长,夜间达到2000 m以上,超过了平时的陆地边界层高度。冷空气过境前后,陆地与湖泊的感热通量此消彼长;冷空气入侵后,水气温差迅速增加而地气温差急剧减小,湖面感热的日累积值迅速增大,风速增加并且垂直方向的风切变增强,这些都为湖泊对流边界层的急剧增长提供了充足的动力。     

干湿地表的湍流特征及其对深对流影响的大涡模拟

利用大涡模式模拟了对流边界层结构演变以及深对流触发过程。通过改变鲍恩比的敏感性试验研究不同大气初始状况下湿润和干旱下垫面湍流特征及其对深对流触发过程的影响。结果表明:干旱下垫面的混合层干而暖,厚度较大;湿润下垫面相反。由于地表感热通量对热力湍流形成的作用更大,干旱下垫面上湍流混合和夹卷作用更强,使得水汽和相当位温在边界层内分布更均一,而在边界层顶有较大的负扰动;干旱下垫面上对流强度较湿润下垫面大,但均表现为泡状对流,水平方向上呈网状结构。不同下垫面上深对流的发生与大气初始状况有关,当初始时刻1—3 km的逆温强度较弱时（0.15 K/（100 m））,边界层内湍流迅速发展,深对流首先在干旱下垫面发生,但因对流有效位能较小,云层厚度小于湿润下垫面。当1—3 km的逆温强度增加到0.55 K/（100 m）时,云层形成时间较晚,云层厚度明显减小,仅当边界层顶的比湿较大时,有深对流发生,但仍首先发生在干旱下垫面,考虑贯穿对流在边界层顶引起的较强冷却作用,云层厚度大于湿润下垫面。      

夏季巴丹吉林沙漠残余层与深厚对流边界层的关系研究

利用2012年7月"巴丹吉林沙漠陆气相互作用及其对区域气候的影响研究"实验所得到的观测资料和中尺度气象模式WRF,对夏季巴丹吉林沙漠对流边界层高度发展的特征及其影响因素进行了研究。结果表明:(1)2012年7月在巴丹吉林沙漠连续观测到厚度超过3500 m的深厚对流边界层,其最大高度可达4000 m以上;当这种深厚对流边界层出现之前,当地中低层大气(1000~4000 m)存在近中性的残余层,而在没有近中性残留层出现时,即便地表感热通量较大,当天最大对流边界层高度却明显偏低;(2)WRF模式模拟结果表明残余层稳定度和对流边界层高度之间的负相关关系在空间区域成立,残余层位温直减率与当地对流边界层高度在时间和空间分布上都呈现显著的负相关关系;残余层位温直减率与对流边界层高度的空间相关系数最大值可达-0.51;(3)观测和模拟结果均表明残余层稳定度会直接影响由感热通量产生的对流边界层的发展效率,进而影响对流边界层的最大高度。通过研究发现,除感热通量外,近中性的残余层是巴丹吉林地区深厚对流边界层出现的关键条件之一。     

大涡模式水平分辨率对边界层夹卷过程及示踪物垂直传输的影响

利用敦煌干旱区野外加密观测资料,结合大涡模式模拟研究模式水平分辨率对边界层对流、夹卷过程及示踪物垂直传输的影响。结果表明:模式水平分辨率越高,模拟的边界层对流泡个数越多,尺度越小,且对流强度越强;提高模式水平分辨率,夹卷层位温方差增大,水平速度方差减小,垂直速度方差增大,且上升冷气流对夹卷层热通量的贡献最大。模式水平分辨率越高,垂直速度、位温及示踪物绝对质量浓度概率密度函数分布变化范围相对越广,且模拟的细微变化特征越清晰。另外,提高模式水平分辨率,模拟的示踪物空间分布特征更加细致,示踪物传输高度也较高。综合考虑到分辨率越高在模拟过程中产生的噪音越大且计算时间越久等问题,认为采用200 m水平分辨率时,模式既能较好地模拟出边界层对流的平均结构,又能模拟出边界层湍流的较细微分布特征,是较为理想的选择。     

高原东南缘大气近地层湍能特征与边界层动力、热力结构相关特征

基于云南省大理2008年3、5、7月GPS加密探空试验时段(14和02时)资料,结合边界层铁塔综合观测资料,采用温度梯度法、逆温强度法和涡动相关法分别计算高原东南缘对流边界层(convective boundary layer,CBL)及稳定边界层(stable boundary layer,SBL)顶高度,通过计算获取感热通量、潜热通量、湍流动能、切变项以及浮力项与大气动力、热力过程垂直相关特征综合分析,可发现湍能方程中浮力项、感热、潜热通量与NCEP再分析资料计算获取的大气视热源相关特征显著,这某种程度反映了高原东南缘近地层大气湍流动量、热量输送对低层大气视热源Q_1的重要贡献。低层视热源Q_1亦表现出与湍能方程分量类似的日变化周期,此特征反映了高原东南缘大气热源变化与下垫面水热过程及其湍流输送日变化密切相关;浮力项与湍能等项对大气低层热源与涡动特征、热力混合结构的形成有重要作用;低层大气视热源、水汽汇均与边界层高度有显著相关,综合分析结果某种程度描述了青藏高原东南缘近地层湍流动量、热量输送状况与低层大气热源,热力混合边界层结构的综合相关物理图像,初步探索了高原东南缘对流活跃区大气湍流运动与大气动力、热力过程相互作用特征。研究表明近地层湍流通量变化某种程度可反映未来局地大气视热源垂直结构变化的"强信号"特征。本文上述研究结论也可启发我们进一步关注近地层湍流通量异常变化特征及其对局地降水过程大气热源结构演变的影响问题。     

感热变化对东亚地区大气边界层高度的影响

利用1979-2009年NCEP/CFSR全球大气边界层高度(PBLH)、感热通量月平均资料,运用多种统计方法,探讨了东亚地区大气边界层高度和感热通量的变化特征,并研究了两个要素场之间的相互关系。结果表明:夏季大气边界层高度东部增高、西部降低,而冬季则与夏季相反。夏季青藏高原地区感热有减少的趋势,其余地区以增加为主;冬季东部地区及新疆西部感热减少,其余地区感热增加。夏季奇异值分析第一模态表明青藏高原地区的感热通量减少时,相应地区的PBLH降低;内蒙古东部和东北地区的感热增加时,相应地区的PBLH增加。该空间型在一定程度上反映了青藏高原、内蒙古东部及东北地区,PBLH变化主要受地表加热影响,且年代际变化显著。夏季奇异值分析第二模态表明当青藏高原南侧、华北的感热增加(减少)时,相应地区的PBLH升高(降低),该空间型年际变化较显著,一定程度上反映了大气边界层高度及感热在高原主体及其南侧分布的差异。冬季奇异值分析第一模态主要表现为在我国东西部反相变化的分布;冬季奇异值分析第二模态表现为华北和华东地区与其余地区反相相关的分布。冬季两个空间型均具有一定的年代际变化特征。在青藏高原及其南侧和西北干旱半干旱区部分地区,PBLH变化主要受地表加热的影响,而在东部季风区,感热变化仅是影响PBLH变化的因素之一。     

初夏敦煌荒漠戈壁大气边界结构特征的一次观测研究

利用"西北干旱区陆气相互作用野外观测实验"加强期在甘肃省敦煌市气象站进行的风、温、湿探空观测资料,分析了西北典型干旱区大气边界层的结构特征和变化规律。结果表明,大气边界层厚度总体而言明显偏高,对流边界最高层厚度可超过4000m,稳定边界层也在1000m左右的高度;2750m附近为风向转变高度,其下全为偏东风,其上全为偏西风,这个风向转变高度有一定日变化,在观测的9天内每天的日变化规律保持了很好的一致性;边界层风速切变较大,大多数时候有低空东风急流出现,急流最强可达到近20m·s-1,急流高度在500m左右;边界层内比湿廓线有时在大约500m高处出现逆湿,一般以夜间更为显著。     

青藏高原中东部地区地表感热通量的时空变化特征

基于1970—2015年青藏高原地区78个站点的观测资料,应用物理方法计算了高原中东部地区的感热通量。利用小波分析、相关性分析等研究了高原中东部感热通量的时空特征和影响因子。结果表明,高原年平均和春夏季节,感热通量周期为3~4 a,而秋冬季节为2~3 a;感热通量的变化趋势为,1970—1980年和2001—2015年感热通量呈增加趋势,而1981—2000年呈减小趋势;高原年平均和各季节的最强感热加热中心均位于高原南坡E区（除冬季外),最弱加热区域位于高原西北部A区（夏季除外);高原春秋季节感热通量的空间分布均匀,冬夏季节有明显的梯度分布且梯度相反,夏季呈现自东到西的梯度;春季、夏季及秋季,高原感热通量和降水呈负相关;高原10 m风速的极值中心随季节北上南撤变化与地气温差的强弱变化共同决定了感热通量的季节变化。     

Performance of WRF Large Eddy Simulations in Modeling the Convective Boundary Layer over the Taklimakan Desert,China

The maximum height of the convective boundary layer (CBL) over the Taklimakan Desert can exceed 5000 m during summer and plays a crucial role in the regional circulation and weather. We combined the Weather Research and Forecasting Large Eddy Simulation (WRF-LES) with data from Global Positioning System (GPS) radiosondes and from eddy covariance stations to evaluate the performance of the WRF-LES in simulating the characteristics of the deep CBL over the central Taklimakan Desert. The model reproduced the evolution of the CBL processes reasonably well, but the simulations generated warmer and moister conditions than the observation as a result of the over-prediction of surface fluxes and large-scale advection. Further simulations were performed with multiple configurations and sensitivity tests. The sensitivity tests for the lateral boundary conditions (LBCs) showed that the model results are sensitive to changes in the time resolution and domain size of the specified LBCs. A larger domain size varies the distance of the area of interest from the LBCs and reduces the influence of large forecast errors near the LBCs. Comparing the model results using the original parameterization of sensible heat flux with the Noah land surface scheme and those of the sensitivity experiments showed that the desert CBL is sensitive to the sensible heat flux produced by the land surface scheme during daytime in summer. A reduction in the sensible heat flux can correct overestimates of the potential temperature profile. However, increasing the sensible heat flux significantly reduces the total time needed to increase the CBL to a relatively low altitude (< 3 km) in the middle and initial stages of the development of the CBL rather than producing a higher CBL in the later stages.     

Regional-Scale Heat and Water Vapour Fluxes in an Agricultural Landscape: An Evaluation of CBL Budget Methods at OASIS

This paper evaluates convective boundary layer (CBL) budget methods as a tool for estimating regionally averaged sensible and latent heat fluxes for the study region used in OASIS (Observations at Several Interacting Scales). This is an agricultural region of mixed cropping and grazing extending about 100 km west of the town of Wagga Wagga, NSW, Australia.The analysis proceeds in three stages: first, a simpleone-dimensional model of the well-mixed layer (the CBL slab model), forced with measurements of the surface heat and evaporation fluxes, is evaluated by comparing measured and modelled CBL temperature, humidity and depths. A comparison of several entrainment schemes shows that a simple model, where the entrainment kinetic energy is parameterised as a fraction (₃) of the surface sensible heat flux, works well if is set to 0.5. Second, the slab model is coupled to a Penman–Monteith model of surface evaporation to predict regional scale evaporation and thence heat fluxes. Finally, the integral CBL budget approach, which is an inverse method using theone-dimensional slab model, is used to infer regional heat and evaporation fluxes from measured time series of CBL temperature and humidity.We find that the simple CBL slab model works reasonably well for predicting CBL depth and very well for CBL temperature, especially if approximate estimates of subsidence velocity and warming due to advection are included. Regional sensible heat fluxes estimated from the integral CBL method match those measured, although the method is very sensitive to measurement errors. Measurement-model differences were larger for short integration times, because the well-mixed assumptions are violated at particular times of the day. The corollary is that `whole-day' (0530–1530 h) estimates are in reasonable agreement with measured values. Integral methods could not be used to infer the regional evaporation flux directly because CBL humidity profiles were complex and often not well mixed until mid-afternoon. We recommend that regional evaporation fluxes be predicted either from a coupled Penman–Monteith – CBL slab model, or inferred as a residual term from estimates of the regionally averaged available energy and sensible heat flux. Furthermore, we show that inferring fluxes via integral methods will always be difficult when the scalar concentrations have either a large surface source and free atmosphere sink (in the case of water vapour and methane), or a large surface sink and upper level source (in the case of CO₂).     

Performance of WRF Large Eddy Simulations in Modeling the Convective Boundary Layer over the Taklimakan Desert,China

The maximum height of the convective boundary layer(CBL)over the Taklimakan Desert can exceed 5000 m during summer and plays a crucial role in the regional circulation and weather.We combined the Weather Research and Forecasting Large Eddy Simulation(WRF-LES)with data from Global Positioning System(GPS)radiosondes and from eddy covariance stations to evaluate the performance of the WRF-LES in simulating the characteristics of the deep CBL over the central Taklimakan Desert.The model reproduced the evolution of the CBL processes reasonably well,but the simulations generated warmer and moister conditions than the observation as a result of the over-prediction of surface fluxes and large-scale advection.Further simulations were performed with multiple configurations and sensitivity tests.The sensitivity tests for the lateral boundary conditions(LBCs)showed that the model results are sensitive to changes in the time resolution and domain size of the specified LBCs.A larger domain size varies the distance of the area of interest from the LBCs and reduces the influence of large forecast errors near the LBCs.Comparing the model results using the original parameterization of sensible heat flux with the Noah land surface scheme and those of the sensitivity experiments showed that the desert CBL is sensitive to the sensible heat flux produced by the land surface scheme during daytime in summer.A reduction in the sensible heat flux can correct overestimates of the potential temperature profile.However,increasing the sensible heat flux significantly reduces the total time needed to increase the CBL to a relatively low altitude(3 km)in the middle and initial stages of the development of the CBL rather than producing a higher CBL in the later stages.     

卫星遥感结合气象资料计算的西北干旱区地面感热特征分析

选取1981年7月-2006年12月美国国家海洋和大气局(NOAA)系列卫星观测的归一化植被指数(NDVI)资料和Ch-INDV参数化关系式,计算了我国西北干旱区84个测站历年各月的地表热力输送系数Ch值和地面感热通量序列,得到如下主要结论:(1)西北干旱区地面感热通量实际计算值与ERA-40再分析感热资料相比,两者在数值大小、分布形势和年际变化趋势上均较一致,感热实际计算值的空间分布更明显地突出了各气象站所在区域的局地特征。(2)西北干旱区地面感热输送呈单峰型年变化特征,春、夏季非常强,秋、冬季较弱;大部分区域全年均为正值,地表为感热源。(3)以97.5°E为界,西北干旱区东、西部具有不同的年际变化趋势,东部的地面感热四季均有逐年增加的趋势,而西部秋、冬季逐年略有增加,春、夏季逐年减弱明显,气候倾向率分别为-1.15 W.m-2.(10a)-1和-2.08W.m-2.(10a)-1。(4)西北干旱区地面感热输送具有明显的年代际变化特征,1980年代总体偏强,1990年代总体偏弱,2000年以来,西北地区中部的感热输送偏弱,东、西部除个别测站外均偏强。(5)西北干旱区的感热变化并不只由地气温差的变化来决定,它与地面风速和地表状况的变化也有较强的依赖关系。在冬季,主要响应地气温差的变化,春季地面风速和地气温差的影响作用同等重要,夏季以地面风速的影响为主,地气温差的影响次之,秋季与夏季相反。另外,夏季地表状况对感热的影响作用也不容忽视。     

The different influence of the residual layer on the development of the summer convective boundary layer in two deserts in northwest China

The development of the atmospheric boundary layer is closely connected with the exchange of momentum, heat, and mass near the Earth’s surface, especially for a convective boundary layer (CBL). Besides being modulated by the buoyancy flux near the Earth’s surface, some studies point out that a neutrally stratified residual layer is also crucial for the appearance of a deep CBL. To verify the importance of the residual layer, the CBLs over two deserts in northwest China (Badan Jaran and Taklimakan) were investigated. The summer CBL mean depth over the Taklimakan Desert is shallower than that over the Badan Jaran Desert, even when the sensible heat flux of the former is stronger. Meanwhile, the climatological mean residual layer in the Badan Jaran Desert is much deeper and neutrally stratified in summer. Moreover, we found a significant and negative correlation between the lapse rate of the residual layer and the CBL depth over the Badan Jaran Desert. The different lapse rates of the residual layer in the two regions are partly connected with the advection heating from large-scale atmospheric circulation. The advection heating tends to reduce the temperature difference in the 700 to 500-hPa layer over the Badan Jaran Desert, and it increases the stability in the same atmospheric layer over the Taklimakan Desert. The advection due to climatological mean atmospheric circulation is more effective at modulating the lapse rate of the residual layer than from varied circulation. Also, the interannual variation of planetary boundary layer (PBL) height over two deserts was found to covary with the wave train.     

Impacts of Aerosol Shortwave Radiation Absorption on the Dynamics of an Idealized Convective Atmospheric Boundary Layer

We investigated the impact of aerosol heat absorption on convective atmospheric boundary-layer (CBL) dynamics. Numerical experiments using a large-eddy simulation model enabled us to study the changes in the structure of a dry and shearless CBL in depth-equilibrium for different vertical profiles of aerosol heating rates. Our results indicated that aerosol heat absorption decreased the depth of the CBL due to a combination of factors: (i) surface shadowing, reducing the sensible heat flux at the surface and, (ii) the development of a deeper inversion layer, stabilizing the upper CBL depending on the vertical aerosol distribution. Steady-state analytical solutions for CBL depth and potential temperature jump, derived using zero-order mixed-layer theory, agreed well with the large-eddy simulations. An analysis of the entrainment zone heat budget showed that, although the entrainment flux was controlled by the reduction in surface flux, the entrainment zone became deeper and less stably stratified. Therefore, the vertical profile of the aerosol heating rate promoted changes in both the structure and evolution of the CBL. More specifically, when absorbing aerosols were present only at the top of the CBL, we found that stratification at lower levels was the mechanism responsible for a reduction in the vertical velocity and a steeper decay of the turbulent kinetic energy throughout the CBL. The increase in the depth of the inversion layer also modified the potential temperature variance. When aerosols were present we observed that the potential temperature variance became significant already around $0.7z_i$ (where $z_i$ is the CBL height) but less intense at the entrainment zone due to the smoother potential temperature vertical gradient.     

藏东南峡谷地区不同下垫面地表通量变化特征及其与降水的关系

利用藏东南峡谷地区排龙站、丹卡站、卡布站、墨脱站四个站点2018年11月至2019年10月的涡动协方差仪观测资料,分析藏东南峡谷地区不同位置入口、中段和末端地表通量变化的特征及其与局地降水的关系.研究表明:地表通量月平均日变化特征为夜间潜热通量大于感热通量,日间呈单峰变化特征.排龙站和丹卡站感热11月至次年4月较强,5...     

黄河源区鄂陵湖湖面和湖边草地对流边界层湍流结构特征的大涡模拟研究

为研究黄河源区边界层湍流特征及其对物质和能量输送的影响,本文首次采用大涡模拟的方法,对比分析了黄河源区两种不同下垫面上（鄂陵湖和湖边草地）对流边界层（CBL）中精细的湍流结构特征。使用资料为2012年夏季黄河源区鄂陵湖流域野外观测实验的GPS探空资料、涡动相关观测资料。分析表明,模拟的黄河源区草地和湖上CBL的平均结构与实测结果吻合较好,但草地和湖上CBL的湍流结构特征差异较明显。模拟结果显示,草地CBL内湍能收支、湍流特征量的时空分布和湍涡结构特征均与陆地上热力驱动CBL的研究结果一致;湖上CBL顶部存在明显的对流卷特征,且夹卷层的湍流强度比草地的强,而草地近地面湍强则更大。通过改变水平分辨率的模拟试验,发现两个不同下垫面上模拟结果对模式分辨率的敏感性不同,湖面CBL的模拟要选择较高的水平分辨率（50～100 m）,以提高近湖面和夹卷层对湍流动能和湍流通量模拟的精度,也充分模拟出各种尺度的波对湍流通量的累积贡献。考虑到计算时间等影响,模拟草地边界层精细的湍流结构时建议选择网格距为100～200 m。     

关于用台站资料估算西北干旱区夏季感热通量的热力参数化比较

气象台站观测的气象要素可能受城市化等因子的影响而与野外试验站的观测存在一定的差异,这影响野外试验获取的热力参数直接应用于西北干旱区台站感热通量的估算。本文选取了一些常用的热力参数化方案(包括Z10、B82、Z98、Y08和Z12等方案),通过敦煌站夏季估算的感热通量与野外观测的比较以及对整个西北干旱区夏季感热通量的估算,评价了这些热力参数化对动量粗糙度的敏感性和在西北干旱区的适用性。结果显示,热力输送系数取定值的方案计算西北干旱区的感热通量可能存在较大不确定;台站的动量粗糙度可能受城市化等因子的影响,但在感热通量计算时建议取台站下垫面的动量粗糙度;Y08方案估算的感热通量相对比较合理,可以用来研究西北干旱区的夏季地表感热输送特征。