The Characteristics and Parameterization of Aerodynamic Roughness Length over Heterogeneous Surfaces

Aerodynamic roughness length （Z0m） is a key factor in surface flux estimations with remote sensing algorithms and/or land surface models. This paper calculates ZOrn over several land surfaces, with 3 years of experimental data from Xiaotangshan. The results show that Z0m is direction-dependent, mainly due to the heterogeneity of the size and spatial distribution of the roughness elements inside the source area along different wind directions. Furthermore, a heuristic parameterization of the aerodynamic roughness length for heterogeneous surfaces is proposed. Individual Z0m over each surface component （patch） is calculated firstly with the characteristic parameters of the roughness elements （vegetation height, leaf area index, etc.）, then Z0m over the whole experimental field is aggregated, using the footprint weighting method.

Development and test of a multifactorial parameterization scheme of land surface aerodynamic roughness length for flat land surfaces with short vegetation

Aerodynamic roughness length is an important physical parameter in atmospheric numerical models and micrometeorological calculations, the accuracy of which can affect numerical model performance and the level of micrometeorological computations. Many factors influence the aerodynamic roughness length, but formulas for its parameterization often only consider the action of a single factor. This limits their adaptive capacity and often introduces considerable errors in the estimation of land surface momentum flux(friction velocity). In this study, based on research into the parameterization relations between aerodynamic roughness length and influencing factors such as windflow conditions, thermodynamic characteristics of the surface layer, natural rhythm of vegetation growth, ecological effects of interannual fluctuations of precipitation, and vegetation type, an aerodynamic roughness length parameterization scheme was established. This considers almost all the factors that affect aerodynamic roughness length on flat land surfaces with short vegetation. Furthermore, using many years' data recorded at the Semi-Arid Climate and Environment Observatory of Lanzhou University, a comparative analysis of the application of the proposed parameterization scheme and other experimental schemes was performed. It was found that the error in the friction velocity estimated by the proposed parameterization scheme was considerably less than that estimated using a constant aerodynamic roughness length and by the other parameterization schemes. Compared with the friction velocity estimated using a constant aerodynamic roughness length, the correlation coefficient with the observed friction velocity increased from 0.752 to 0.937, and the standard deviation and deviation decreased by about 20% and 80%, respectively. Its mean value differed from the observed value by only 0.004 ms^(-1) and the relative error was only about 1.6%, which indicates a significant decrease in the estimation error of surface-layer momentum flux. The test results show that the multifactorial universal parameterization scheme of aerodynamic roughness length for flat land surfaces with short vegetation can offer a more scientific parameterization scheme for numerical atmospheric models.

The Influences of Thermodynamic Characteristics on Aerodynamic Roughness Length over Land Surface

It has previously been shown that aerodynamic roughness length changes significantly along with near- surface atmospheric thermodynamic state; however, at present, this phenomenon remains poorly understood, and very little research concerning this topic has been conducted. In this paper, by using the data of different underlying surfaces provided by the Experimental Co-observation and Integral Research in Semi-arid and Arid Regions over North China, aerodynamic roughness length （z0） values in stable, neutral, and unstable atmospheric stratifications are compared with one another, and the relationship between z0 and atmospheric thermodynamic stability （（） is analyzed. It is found that z0 shows great differences among the stable, neutral, and unstable atmospheric thermodynamic states, with the difference in z0 values between the fully thermodynamic stable condition and the neutral condition reaching 60% of the mean z0. F^trthermore, for the wind speed range in which the wind data are less sensitive to z0, the surface z0 changes more significantly with （, and is highly correlated with both the Monin-Obukhov stability （4o） and the overall Richardson number （Rib）, with both of their correlation coefficients greater than 0.71 and 0.47 in the stable and unstable atmospheric stratification, respectively. The empirical relation fitted with the experimental observations is quite consistent with the Zilitinkevich theoretical relation in the stable atmosphere, but the two are quite distinct and even show opposite variation tendencies in the unstable atmosphere. In application, however, verification of the empirical fitted relations by using the experimental data finds that the fitted relation is slightly more applicable than the Zilitinkevich theoretical relation in stable atmospheric stratification, but it is much more suitable than the Zilitinkevich relation in unstable atmospheric stratification.

Interaction of aerodynamic roughness length and windflow conditions and its parameterization over vegetation surface

Surface aerodynamic roughness length is usually taken as a constant. In fact, it displays a remarkable dynamic change over underlying vegetation surfaces, because of the coupling of land surface roughness elements and windflow conditions. Current international research on this dynamic change and associated mechanisms is very limited. Using observations from different underlying surfaces (including forest, farmland and grassland) provided by a northern China coordinated observation test, the variation of aerodynamic roughness length, along with wind speed and friction velocity, is analyzed. We introduce two relationship fits, between aerodynamic roughness length and wind speed u, and dynamic variable u2/u*. Results show that aerodynamic roughness length has a clear dynamic change, and has complicated interactions with near-surface windflow. Further, the relationship fits between aerodynamic roughness length, u and u2/u*, are not only related to the roughness properties of the underlying vegetation surface (e.g. plant height), but also to plant dynamic response characteristics (e.g. flexibility). Aerodynamic roughness length decreases with increasing wind speed, because near-surface windflow conditions can change both plant roughness properties and airflow. However, the change of aerodynamic roughness length with friction velocity is complicated, and its sensitivities and transition points significantly depend on vegetation type. For underlying surfaces of forest and corn, with relatively substantial vegetative cover, roughness length correlates well with wind speed. For a surface with short vegetative cover, like natural lawn, the correlation is low. However, for all of the three vegetative surfaces, there is a close relation between roughness length and u2/u*, and their coefficients of fit from testing essentially represent the plant height and flexibility of different vegetation types. The test results also indicate that the parameterized relationships of roughness length over the underlying vegetation surface hold prospects for application.

The impact of heterogeneity of land surface roughness length on estimation of turbulent flux in model

Based on preliminary theoretical analysis and numerical experiment, it is found that land surface heterogeneity plays an important role in the models turbulent flux calculation. In nearly neutral atmosphere conditions, variation coefficient of sub-scale roughness length, cell-average roughness, and reference height are main factors affecting the calculation of grid turbulent fluxes. The first factor has a determinant role on calculation deviation. The relative error generated by roughness heterogeneity could be more than 40% in some cases in certain areas （e.g., in vegetation-climate transition belt）. Selecting a specific reference height may improve the calculation of turbulent flux. In stable or unstable atmosphere conditions, with sensible heat flux as an example, analysis shows that the discrepancy is correlated to the sub-grid distributions of mean wind velocity, potential temperature gradient between land surface and reference levels, and atmosphere stability near surface layer caused by the heterogeneity of land surface roughness. The calculation of turbulent flux is the most sensitive to stability in the above three factors. The above analysis shows that it is necessary to make a further consideration for the calculation deviation of the turbulent fluxes brought from land surface heterogeneity in the present numerical models.

Surface roughness length dynamic over several different surfaces and its effects on modeling fluxes

Roughness length and zero-plane displacement over three typical surfaces were calculated iteratively by least-square method, which are Yucheng Experimental Station for agriculture surfaces, Qianyanzhou Experimental Station for complex and undulant surfaces, and Changbai Mountains Experimental Station for forest surfaces. On the basis of roughness length dynamic, the effects of roughness length dynamic on fluxes were analyzed with SEBS model. The results indicate that, aerodynamic roughness length changes with vegetation conditions (such as vegetation height, LAI), wind speed, friction velocity and some other factors. In Yucheng and Changbai Mountains Experimental Station, aerodynamic roughness length over the fetch of flux tower changes with vegetation height and LAI obviously, that is, with the increase of LAI, roughness length increases to the peak value firstly, and then decreases. In Qianyanzhou Experimental Station, LAI changes slightly, so the relationship between roughness length and LAI is not obvious. The aerodynamic roughness length of Yucheng and Changbai Mountains Experimental Station changes slightly with wind direction, while aerodynamic roughness length of Qianyanzhou Experimental Station changes obviously with wind direction. The reason for that is the terrain in Yucheng and Changbai Mountains Experimental Station is relatively flat, while in Qianyanzhou Experimental Station the terrain is very undulant and heterogeneous. With the increase of wind speed, aerodynamic roughness length of Yucheng Experimental Station changes slightly, while it decreases obviously in Qianyanzhou Experimental Station and Changbai Mountains Experimental Station. Roughness length dynamic takes great effects on fluxes calculation, and the effects are analyzed by SEBS model. By comparing 1 day averaged roughness length in Yucheng Experimental Station and 5 day averaged roughness length of Qianyanzhou and Changbai Mountains Experimental Station with roughness length parameter chosen by the model, the effects of roughness length dynamic on flux calculation is analyzed. The maximum effect of roughness length dynamic on sensible heat flux is 2.726%, 33.802% and 18.105%, in Yucheng, Qianyanzhou, and Changbai Mountains experimental stations, respectively.

黄土高原半干旱区非均一下垫面粗糙度分析

利用2007年4月17日—2008年4月16日兰州大学半干旱气候与环境观测站边界层气象塔的风速、风向、温度、气压、湿度等观测资料,采用经典的廓线法和风速、风向标准差法,分别计算了中性大气层结下观测站下垫面粗糙度长度,并得到了具有黄土高原地理特征的地表粗糙度及其时空变化特征。计算结果表明,季节变化对粗糙度的影响幅度可达0.159 m,空间非均一性对粗糙度的影响幅度可达0.155 m。测站附近粗糙度春季为0.017 m,夏季为0.062 m,秋季为0.065 m,冬季为0.018m。测站西北方向上游粗糙度春季为0.17 m,夏季为0.22 m,秋季为0.34 m,冬季为0.05 m。测站东南方向上游粗糙度春季为0.11 m,夏季为0.17 m,秋季为0.19 m,冬季为0.05 m。该站下垫面粗糙度计算宜选用风速为6±1.5 m.s-1,风向变化30°范围内的数据。

塔克拉玛干沙漠腹地地气相互作用参数研究

利用塔克拉玛干沙漠腹地塔中A站2008年7月-2009年7月的连续观测数据,分析了沙漠地气相互作用的几个关键参数。结果表明:(1)地表反照率的计算需选取太阳高度角≥10°的数据,其日均值季节性变化明显,冬季高、夏季低,年均值为0.270±0.003。(2)土壤热容量和热传导率也具有明显的季节变化,冬季值稳定且低而夏季值不稳定且高。平均土壤热容量、热传导率和热扩散率分别为1.559(±0.140)×106 J.m-3.K-1、0.234(±0.021)W.m-1.K-1和1.504(±0.110)×10-7 m2.s-1。(3)地表比辐射率值为0.91。(4)动力学粗糙度远低于国内其他沙漠,值的范围是(2.7～8.0)×10-5 m,比敦煌和黑河试验中的值小2个量级。但在冬季时其值偏大,达到(21.04～91.32)×10-5 m。

地表粗糙度非均匀性对模式湍流通量计算的影响

理论分析和数值试验结果表明,地表参量的不均匀性对网格区地表湍流通量的计算有重要影响。近中性大气层结条件下,次网格粗糙度长度的变差系数、网格平均粗糙度及参考高度的选取是影响网格湍流通量计算的主要因素,其中次网格粗糙度长度的变差系数对计算偏差起主要决定作用。实际计算表明,某些特定地区(如植被气候过渡带)粗糙度的地表非均匀性引起的计算相对误差可达40%以上,选取特定的参考高度能改善高网格湍流通量计算的效果。非中性大气层结条件下,由地表粗糙度不均匀性所致的平均风速、位温梯度以及近地层大气稳定度的次网格分布都对网格湍流通量(感热通量)计算产生影响,比较而言,相对误差大小对大气稳定度的次网格分布最为敏感。所以,在目前的数值模式中有必要进一步对湍流通量计算过程中由于地表不均匀性产生的计算偏差加以考虑。

生物结皮粗糙特征——以古尔班通古特沙漠为例

空气动力粗糙度可以反映地表气流与下垫面的相互作用。古尔班通古特沙漠是我国最大的固定、半固定沙漠,其间广泛分布的生物结皮在稳定地表和改善环境方面意义重大。对未经扰动的4种类型生物结皮进行表面微形态观察,并通过风洞实验确定动力粗糙度z0和摩阻风速u*,结果表明:(1)不同生物结皮类型,其组成和表面微形态等都具有明显差异。藻结皮以表面致密光滑为显著特征,由藻类分泌物和藻丝体粘结细粒物质所形成;地衣结皮表面藻类和真菌形成的叶状体匍匐沙面生长,呈现三维生长方式,形成有明显凹凸的壳状覆被;苔藓结皮以苔藓植物体密集丛生为特点,地上部分出现了茎叶分化,有一定的柔韧性。(2)就动力粗糙度的大小而言,是按地衣结皮>藻类-地衣结皮>苔藓结皮>藻结皮的顺序排列的,z0平均值依次为(6.589±0.850)mm、(4.179±0.239)mm、(2.542±0.357)mm和(0.393±0.220)mm,与定床裸沙面的(0.042±0.019)mm相比,生物结皮z0值提高了10—150倍。随着风速的增大z0值有所减小,其中以地衣结皮的减小趋势较为明显。(3)由风速廓线对比发现,4类生物结皮对气流阻滞作用的差异主要局限于4 cm以下的高度范围,风速越大这种差异也越大。各类生物结皮摩阻风速u*随风速增大而增大,其中藻结皮的增大速率明显低于其它3类结皮,说明藻结皮随风速增大的阻滞效应较其它3类结皮要差。(4)在净风条件下,地衣结皮具有最好的防风效果,其次为藻类-地衣结皮和苔藓结皮,藻结皮最差。当生物结皮破损后,床面结构和气流性质将发生变化,对空气动力学粗糙度和摩阻风速产生的影响将有待于进行更深入的研究。

黄河上游玛曲地区空气动力学参数的确定及其在陆面过程模式中的应用

为了定量描述黄河上游玛曲地区草地下垫面的空气动力学特征,为模式提供准确的下垫面参数,利用"黄河源区气候与环境综合观测研究站"2006年9月的湍流观测资料,结合Martano由单层超声观测资料确定下垫面空气动力学参数的方法,计算了黄河上游玛曲地区草原下垫面空气动力学粗糙度z0和零平面位移d,即z0为0.035 m,d为0.143 m。同时,将z0和d应用于陆面过程模式CoLM中,检验其对模式模拟性能的影响,结果表明,改进陆面参数后的模式对感热通量和潜热通量的模拟均有明显改善。

戈壁下垫面空气动力学参数确定的再研究

提出一种确定地表粗糙度z0的方法。该方法仅需利用精细风廓线资料进行计算,误差较小,尤其适用于近中性层结观测较困难的情况。根据2006年夏季河西走廊戈壁地区的大气边界层观测资料,利用该方法确定的z0为0.60 mm左右,和前人方法计算结果0.78 mm接近,证实了此方法和z0数值的可靠性和可信度。此外,由于不同测量高度代表不同区域尺度上的特征,地表粗糙度的确定还应考虑风廓线的观测高度及分布状态。

复杂地形条件下零平面位移和空气动力学粗糙度的计算——以珠海南亚热带常绿阔叶林地区为例

空气动力学粗糙度和零平面位移是影响陆面过程的重要参数。以往对空气动力学粗糙度和零平面位移的计算往往针对均一程度较高的下垫面。以珠海南亚热带常绿阔叶林地区为例,探索了复杂地形下垫面空气动力学粗糙度和零平面位移的计算。用拟合法和粗糙元法计算了该地区下垫面的空气动力学粗糙度和零平面位移,并分析了两种方法的误差来源。计算结果表明,拟合法在这种复杂地形下的计算准确度并不理想,由于这种方法的代表范围较小,易受到周边地形影响而使测量结果不符合对数廓线的形式,从而得不到准确的结果。与拟合法相比,粗糙元法可以给出所计算下垫面的具体范围。粗糙元法计算结果的代表范围比拟合法大得多,因此,粗糙元法比拟合法更加能够反映的是该区域下垫面空气动力学粗糙度和零平面位移的总体情况。另外,粗糙元法可以计算那些因为风速资料不足无法用风速廓线直接加以计算的区域的空气动力学粗糙度和零平面位移。根据拟合法的计算结果,冬季315-45°范围内,z0=2.96m,d=22.48m;45-135°范围内,z0=1.26m,d=8.81m。春夏季315-45°范围内,z0=3.90m,d=27.00m;45-135°范围内,z0=1.51m,d=14.83m。根据粗糙元法的计算结果,东南西北四个方向1km×1km范围内z0分别为0.94m、1.28m、1.30m、2.08m;d分别为13.87m、18.79m、19.12m、30.61m。

夏季风影响过渡区的动力学粗糙度的特征分析

利用北方协同观测试验中夏季风影响过渡区榆中站、定西站和兴隆山站观测资料,分别代表草地、农田、混合型下垫面,采用通量廓线方法计算了各下垫面的粗糙度,分析了下垫面动力学粗糙度随风向、风速、摩擦速度和热力稳定度的变化特征及其与风速、热力稳定度的参数化关系.结果表明,动力学粗糙度随风向有明显的变化,因风向区间通量的不同而不同;动力学粗糙度与风速整体呈负相关,且在不同站点存在显著差异,在草地和混合型下垫面的相关性较好,而在农田下垫面相关性较差.动力学粗糙度与摩擦速度的关系相对较为复杂,在小摩擦速度区间随摩擦速度递增而递增,在大摩擦速度区间随摩擦速度的递增而递减.大气稳定时,粗糙度随热力稳定度呈显著负相关,大气活跃时,粗糙度随热力稳定度呈正相关.

北京城市下垫面动力学参数的计算与分析

采用北京325 m铁塔2008—2012年的单层超声观测资料,基于莫宁-奥布霍夫相似理论(Monin-Obukhov similarity theory)和前人提出的最小误差分析方法,计算了铁塔周边下垫面的零平面位移高度和动力粗糙度长度。结果表明,由于铁塔位于北京市区,其周边下垫面呈现极其复杂的非均匀性,所以对应铁塔周边不同的扇区,零平面位移高度和动力粗糙度长度各有不同。平均而言,在2008—2012年间,铁塔周边下垫面的零平面位移高度为34.4 m,动力粗糙度长度为1.16 m。此外,综合前人的计算结果发现,铁塔周边的零平面位移高度和动力粗糙度长度在2001年之前呈显著增加的趋势,而在2001年以后并未增长,这一现象与铁塔周边的城市化进程相对应。

基于遥感和实测数据对台风LEO和SOULIK期间的飞沫热通量研究

本文应用高风速条件下海面动力粗糙度长度,拓展了COARE3.0块体通量算法,考虑高风速下,海洋飞沫对热通量的贡献。利用GSSTF3(Goddard Satellite-based Surface Turbulent Fluxes Version 3)遥感产品、GSSTF_NCEP(National Centers Environmental Prediction)再分析资料和浮标KEO实测数据,探讨了中国南海台风LEO和西北太平洋台风SOULIK期间湍流热通量的变化。研究结果表明:感热通量与潜热通量相比很小;台风的轨迹与潜热通量的分布密切相关且在台风轨迹的东偏北区域潜热通量数值大;在热带低压之前,原潜热通量与改进后潜热通量的差值即飞沫热通量很小,随着台风等级的增加,飞沫热通量也增加。当台风LEO达到最高即台风级别时原潜热通量达到300W/m2,飞沫热通量与原通量的比值高达12%,而台风SOULIK达到强台风级别时原潜热通量达到1000W/m2,飞沫热通量与原通量的比值达到20%,显著高于台风LEO,飞沫效应更明显。

植被下垫面Z_(0)的估算及其改进影响评估

利用卫星遥感反演数据和多种观测资料,基于形态学-遥感反演的方法,估算我国主要植被下垫面的空气动力学粗糙度长度(Z_(0)),将其应用于区域大气化学模式(WRF-Chem)中改进模式默认Z_(0)值,并结合全国气象和污染物观测数据进行改进效果评估,探究Z_(0)改进对模式气象场和化学场模拟结果的影响.结果表明:(1)Z_(0)高值主要位于森林类下垫面,可超过1m;农田、草地类下垫面Z_(0)值较小,低于0.5m,其余植被下垫面的Z_(0)值基本介于两者之间.(2)Z_(0)改进后,10m风速(WS10)和地表温度(TSK)的改进效果较好,而2m温度(T2)和相对湿度(RH)的改进效果不明显;从空间分布和不同下垫面结果来看,Z_(0)对TSK主要是增温作用,对WS10是减小作用;就改进比(各要素改进后的模拟值与改进前的模拟值之差比上改进前的模拟值,下同)而言,Z_(0)改进对WS10的影响大于TSK.从对污染物浓度效果评估看,Z_(0)对PM_(2.5)和PM_(10)模拟改进效果较好,对其它污染物(SO_(2)、NO_(2)、O_(3))的改进效果不明显.(3)对比气象要素和污染物浓度效果评估可知,Z_(0)改进对气象要素的影响大于污染物浓度,其主要是通过影响气象场来间接影响污染物浓度.总的来看,Z_(0)改进影响最大的是气象场的10m风速,考虑其原因在于改进后的Z_(0)普遍高于改进前模式默认Z_(0)值,而Z_(0)是表征地表粗糙度的变量,由于地表粗糙度的增加,增强了对气流的阻碍作用,使得近地层风速减小.