不同平均时间对LOPEX10资料涡动相关湍流通量计算结果影响的探讨

通过处理涡动相关系统观测的近地层湍流脉动量可以获取地—气间感热和潜热通量,然而选择不同平均时间对通量计算的结果有较大影响。采用黄土高原陆面过程野外观测试验(LOPEX10)期间获得的涡动相关系统观测资料,分析了不同平均时间对湍流通量计算的影响,并采用雷诺平均和分解方法推导了平均时间引起的通量差值的数学表达式(Flux Compensation,FC)。结果表明:(1)FC公式可以说明采用不同平均时间数据之间的关系,也可以直接计算低频涡旋对湍流通量的贡献。FC公式计算的结果与直接计算的不同平均时间通量计算之差的相关系数在0.95以上,并可以确定计算湍流通量的最佳平均时间。(2)通过采用Ogive函数确定了计算LOPEX10期间通量的最佳平均时间长度为30min,印证了利用雷诺平均和分解方法计算湍流通量补偿的准确性。(3)通过进一步的数学变换,证明了平均时间对湍流通量计算的影响直接与湍流低频变化相关,FC公式可以用来确定涡动相关观测数据的最佳平均时间,并且在获得较高时间分辨率的湍流通量数据的同时,补偿因平均时间过短而遗漏的低频信息。     

GAMIL模式海气湍流通量参数化方案的改进及其对大气环流年际变率模拟效果的影响

通过引人中尺度对流运动对海表湍流通量的贡献,改进了大气环流模式GAMIL1.0的海气湍流通量参数化方案.利用1979年1月至2000年12月的观测海温资料驱动GAMIL1.0模式,研究了海气湍流通量参数化改进对大气环流年际变化模拟效果的影响.结果表明:采用改进的海气湍流通量参数化方案,模拟的热带海表湍流热通量得到增强,...     

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。     

那曲高寒草地上四种地表通量计算方法的对比

利用中国科学院那曲高寒气候环境观测研究站2013年9月至2014年8月自动气象站(AWS)和涡动相关系统(EC)的观测资料,基于空气动力学法、地表能量平衡组合法、总体输送法以及涡动相关法,计算了高寒草地下垫面的湍流通量,并对不同方法计算结果间的一致性和差异性进行了分析。结果表明,不同方法计算的湍流通量特征具有明显的差异。地表能量平衡组合法满足能量平衡关系,但在早晨和傍晚层结转换期间,计算的湍流通量出现异常不稳定值;空气动力学法计算的湍流通量在整个观测期与涡动相关法计算的湍流通量相关性最高,但在大气稳定度参数接近0,计算结果不稳定;总体输送法计算的通量数据在地气温差为负值时发散明显,但该方法原理简单,适合在只有常规观测项目的业务气象站或在气象观测项目不全的野外台站使用。空气动力学法和地表能量平衡组合法与涡动相关法的湍流通量的平均偏差相对较小,而总体输送法平均偏差相对较大。研究方法和结果除了为这些方法的使用提供参考外,也为建立长时间通量序列提供了一个较为合理的依据,有助于深入了解高原地气相互作用。     

云贵高原西部大理地区近地层湍流特征分析

利用大理国家气候观象台2007年3—12月观测资料,采用涡动相关法等计算方法分析了该地区湍流强度、湍流方差、湍流通量等特征量的日变化和干湿季变化特征。结果表明,湍流强度干季大于湿季;湍流方差与稳定度满足1／3次方定律,风速方差在稳定条件下比不稳定条件下离散,水平方向比垂直方向离散;湍流通量有明显日变化特征,感热、动量通量干季大于湿季,潜热通量湿季大于干季,干湿季热量交换以潜热为主;干季能量闭合率大于湿季;不同风向条件下平均水汽密度存在差异.     

云南大理干湿季近地层湍流特征对比分析

利用大理国家气候观象台2007年3月至2008年1月观测资料,采用涡动相关法等计算方法分析了该地区湍流强度、湍流方差、湍流通量等特征量的日变化规律和干湿季变化特征。结果表明：湍流强度干季大于湿季;湍流方差与稳定度满足1／3次方定律,风速方差在稳定条件下比不稳定条件下离散,水平方向比垂直方向离散;湍流通量有明显日变化特征,感热、动量通量干季大于湿季,潜热通量湿季大于干季,干湿季热量交换以潜热为主。     

青藏高原典型下垫面地表能量通量的模型估算与验证

青藏高原地区地表能量通量的估算与验证对高原及其周边地区能量和水循环研究具有重要意义,地表能量平衡系统SEBS(Surface Energy Balance System)模型为研究高原非均匀地表区域地表能量通量提供了一种行之有效的方法。基于中国科学院那曲高寒气候环境观测研究站(简称那曲站)、中国科学院纳木错多圈层综合观测研究站(简称纳木错站)和中国科学院珠穆朗玛大气与环境综合观测研究站(简称珠峰站) 2008年辐射资料、大气边界层塔站观测资料,结合MODIS卫星数据,利用SEBS模型估算地表能量通量,并用站点地表能量通量观测资料进行验证。结果表明,模型估算的感热通量和土壤热通量与站点实测值具有较好的一致性,且感热通量和土壤热通量的估算精度明显优于潜热通量;感热通量的估算精度最高,那曲站、纳木错站和珠峰站的均方根误差分别为54. 98,37. 37和27. 10 W·m~(-2);而模型估算的潜热通量验证结果偏差较大和站点实测数据存在"能量不闭合"问题相关。鉴于在地表能量通量观测中广泛存在"能量不闭合"的问题,利用波文比校正方法校正站点实测潜热通量。研究表明波文比校正方法可以明显改善地表通量观测数据"能量不闭合"的问题,那曲站、纳木错站和珠峰站的能量闭合率分别提高了19. 4%,21. 4%和19. 1%;与原始站点实测潜热通量相比,校正后的潜热通量与SEBS模型估算结果一致性较好,3个站点潜热通量的均方根误差分别减少了6. 78,33. 48和29. 30 W·m~(-2)。     

山谷城市的近地层大气湍流谱特征

山谷城市地区的大气湍流结构研究至今报道很少.本文根据兰州市一次观测实验,对各风速分量谱、温度谱以及动量和感热通量的协谱进行了分析.结果表明,尽管仪器的安装高度较低(6.45m),湍谱特征仍与平坦均匀下垫面得到的一些典型结果基本一致,从而认为,在类似地区进行湍流通量等的直接观测时,对观测高度和地点的选择,可以不必象一些文献要求的那样高.     

台风“珍珠”登陆期间动量通量的多尺度分析

利用台风"珍珠"登陆前后的近地层湍流观测资料,分析了该台风经过观测场地前后地面气象要素的变化及其动量通量特征。结果表明,台风"珍珠"经过观测场地前后的近地层气象要素发生了急剧的变化,并且在台风前部存在强的中尺度对流系统,反映在风速能谱密度结构上,频率f在3×10-4~2×10-3Hz之间的中尺度信号对能谱的贡献比平稳天气形势下的能谱贡献大很多,尤其是顺风方向风速的能谱密度的峰值与湍流信号的峰值相当;动量通量分析结果表明,台风中心经过观测场地的前后三小时,近地层通量以向下输送的中尺度通量为主,湍流通量的贡献相对于中尺度通量较小,也是向下输送的;而在其他时段,近地层通量主要以向上输送的湍流通量为主,中尺度通量量值很小,可以忽略。     

深圳市西部地区大气湍流通量特征分析

利用2015—2016年深圳市石岩气象综合观测基地开路涡动系统的通量数据及深圳市环境监测中心西乡站污染物浓度资料,分析了深圳市西部地区大气湍流通量特征。结果表明:该区域湍流通量具有明显单峰型日变化且峰值均出现在午后。潜热通量占据主导地位,污染过程的潜热通量比清洁过程的潜热通量大,不同过程中感热通量和动量通量均值及最大值变化程度接近。臭氧生成的条件为弱风、强辐射及干燥天气,当臭氧成为主要污染物时,使得湍流通量日变化具有与清洁过程不同的特征。     

长江三角洲常熟地区近地层湍流特征的研究

利用1999年5－9月长江三角洲常熟地区的湍流脉动观测资料，分析了该地区感热，潜热和动量通量的日变化以及湍流强度和湍流谱特征，结果表明：该地区各能量的日变化与常见情况相同，白天潜热通量的输送占主导地位，感热通量比潜热小得多，且湍流的日变化与天气的关系非常密切，晴天比阴天要大得多。湍流强度和湍流谱的分析结果表明，在近中性条件下，常熟地区各方向湍流强度接近典型平坦下垫面的值。非中性条件下，垂直方向规一化标准差与稳定度的关系都较好地满足1／3次幂定律，水平方向没有垂直方向上的规律好，特别是稳定条件下，数据点分散性大；各风速分量变在高频段满足理论上的－2／3次幂定律，纵向和垂直方向速度谱的峰值频率与典型平坦下垫面上的结果一致，总体输送系数CD，CH与稳定度的关系密切，随稳定度增加有减小的趋势。     

Comparison of atmospheric turbulence characteristics and turbulent fluxes from two urban sites in Essen, Germany

From September 2006 to September 2007, the intersite variability of turbulence characteristics and turbulent heat fluxes was analysed at two urban stations in Essen, Germany. One site was situated within an urban residential setting while the other was located at the border of an urban park and suburban/urban residential housing. Therefore, the surroundings at both sites contributing to surface–atmosphere exchange differed in terms of surface cover and surface morphology. During the 1-year measurement period, 19% of data were characterised by stable atmospheric stratification. Since observations of urban turbulence characteristics under stable stratification are scarce, so far, this work adds additional input to this discussion. Turbulence characteristics, i.e. normalised standard deviations of wind components, were in agreement to empirical fits from other urban observations under both instable and stable atmospheric stratification. However, differences in magnitude of turbulence characteristics between sites were observable. Comparison of turbulent heat fluxes indicated typical urban features in the site located in the urban setting with increased surface heating and higher surface heat fluxes by about 30%. Also the temporal evolution of heat fluxes on the diurnal course was affected. Differences in momentum flux were of minor magnitude with about 6% variation on average between sites. Findings indicate that multiple urban flux measurements within one city may be characterised by general similarities in terms of turbulent characteristics but are still significantly influenced by differences in the surface cover of the flux footprint.     

Aircraft Observations of Sea-Surface Turbulent Fluxes Near the California Coast

Aircraft turbulence data from the Autonomous Ocean Sampling Network project were analyzed and compared to the Coupled Ocean–Atmosphere Response Experiment (COARE) bulk parametrization of turbulent fluxes in an ocean area near the coast of California characterized by complex atmospheric flow. Turbulent fluxes measured at about 35 m above the sea surface using the eddy-correlation method were lower than bulk estimates under unstable and stable atmospheric stratification for all but light winds. Neutral turbulent transfer coefficients were used in this comparison because they remove the effects of mean atmospheric conditions and atmospheric stability. Spectral analysis suggested that kilometre-scale longitudinal rolls affect significantly turbulence measurements even near the sea surface, depending on sampling direction. Cross-wind sampling tended to capture all the available turbulent energy. Vertical soundings showed low boundary-layer depths and high flux divergence near the sea surface in the case of sensible heat flux but minimal flux divergence for the momentum flux. Cross-wind sampling and flux divergence were found to explain most of the observed discrepancies between the measured and bulk flux estimates. At low wind speeds the drag coefficient determined with eddy correlation and an inertial dissipation method after corrections were applied still showed high values compared to bulk estimates. This discrepancy correlated with the dominance of sea swell, which was a usually observed condition under low wind speeds. Under stable atmospheric conditions measured sensible heat fluxes, which usually have low values over the ocean, were possibly affected by measurement errors and deviated significantly from bulk estimates.     

A multi-limit formulation for the equilibrium depth of a stably stratified boundary layer

Currently no expression for the equilibrium depth of the turbulent stably-stratified boundary layer is available that accounts for the combined effects of rotation, surface buoyancy flux and static stability in the free flow. Various expressions proposed to date are reviewed in the light of what is meant by the stable boundary layer. Two major definitions are thoroughly discussed. The first emphasises turbulence and specifies the boundary layer as a continuously and vigorously turbulent layer adjacent to the surface. The second specifies the boundary layer in terms of the mean velocity profile, e.g. by the proximity of the actual velocity to the geostrophic velocity. It is shown that the expressions based on the second definition are relevant to the Ekman layer and portray the depth of the turbulence in the intermediate regimes, when the effects of static stability and rotation essentially interfere. Limiting asymptotic regimes dominated by either stratification or rotation are examined using the energy considerations. As a result, a simple equation for the depth of the equilibrium stable boundary layer is developed. It is valid throughout the range of stability conditions and remains in force in the limits of a perfectly neutral layer subjected to rotation and a rotation-free boundary layer dominated by surface buoyancy flux or stable density stratification at its outer edge. Dimensionless coefficients are estimated using data from observations and large-eddy simulations. Well-known and widely used formulae proposed earlier by Zilitinkevich and by Pollard, Rhines and Thompson are shown to be characteristic of the above interference regimes, when the effects of rotation and static stability (due to either surface buoyancy flux, or stratification at the outer edge of the boundary layer) are roughly equally important.     

盘锦芦苇湿地近地面层湍流通量参数化方案研究

基于2005年盘锦芦苇湿地近地面层湍流通量和微气象梯度的连续观测,研究了芦苇湿地近地面层湍流通量参数化方案。结果表明,盘锦芦苇湿地近地面层经常维持弱稳定和弱不稳定层结。在不稳定层结(-0.4     

A STUDY OF NEAR SURFACE WIND PROFILES IN THE HEBEI COASTAL AREA BASED ON OBSERVATIONAL EXPERIMENTS

In order to provide wind profiles for the microscale numerical simulation of wind farm with complex terrain,using the 100 m tower atmospheric turbulence observation experiment data in 2010 in Hebei Province offered by National Climate Center, the variation characteristics of wind profile under the different atmospheric stability conditions are analyzed, and the wind profile expression based on the local similarity theory is established. The results show that:(1) In spring, the occurrence probability of unstable stratification in the Hebei coastal area is as high as 28%, and the probability of stable stratification is more than 43% while, in summer, the probability of occurrence of unstable stratification is as high as 80% with a lower probability for stable stratification; and(2) for stable stratification, the characteristics of atmosphere change is dramatic in terms of the vertical direction, which need to be treated layer by layer.According to the atmospheric turbulence observation experiment data above, under stable stratification, the relationship between the dimensionless velocity gradient and the stability ζ can be expressed as 1 +βmζ, with βm changing with the height: βm takes 4.1-4.3 under 30 m, βm takes 4.6-4.7 between 30-50 m, and βm takes 6.3-6.7 over 50 m.     

南极近地层大气的热量逆梯度输送现象

根据南极中山站观测结果 ,分析了南极地区近地层热量逆梯度输送的现象。结果表明南极地区在近地层逆温较明显时 ,常会出现热量逆梯度输送的现象 ;同时也探讨了近地层在稳定层结条件下 ,热量逆梯度输送通量的多尺度计算方法。计算结果表明 ,逆梯度输送的感热通量主要是由浮力湍涡的穿越能力决定的 ,而经典的梯度输送公式在该场合下无法使用。     

森林近地层大气湍流特性观测分析

利用长白山森林生态系统定位研究站观测资料,及2003年8月和9月涡旋相关资料,分析和比较了该地区近地层包括风速、风向、大气稳定度在内的平均场特征,以及湍流强度、无量纲化风脉动方差相似性和地表通量变化特征。结果表明:(1)8月和9月稳定度都基本集中在0附近;(2)风速2 m·s-1的环境中,湍流发展最为旺盛,随着风速的增大湍流强度先迅速减小,当风速增大到3 m·s-1后,湍流强度偏离0值变大了一些,再继续增大到一定风速大小以后,湍流强度基本不随风速变化;(3)无量纲化三维风脉动方差符合Monin-Obukhov相似理论的"1/3"定律,其最佳通用相似函数在稳定和不稳定条件下都可以拟合得到;(4)地表通量均表现出明显的日变化特征,8月以潜热为主,感热较小;9月仍以潜热为主,但是相比8月明显偏小,感热变化不大。     

Vertical Structure Of Turbulence In Offshore Flow During Rasex

The adjustment of the boundary layer immediately downstream froma coastline is examined based on two levels of eddy correlation data collected on a mast at the shore and six levels of eddy correlation data and profiles of mean variables collected from a mast 2 km offshore during the Risø Air-Sea Experiment. The characteristics of offshore flow are studied in terms of case studies and inter-variable relationships for the entire one-month data set. A turbulent kinetic energy budget is constructed for each case study.The buoyancy generation of turbulence is small compared to shear generation and dissipation. However, weakly stable and weakly unstable cases exhibit completely different vertical structure. With flow of warm air from land over cooler water, modest buoyancy destruction of turbulence and reduced shear generation of turbulence over the less rough sea surface cause the turbulence to rapidly weaken downstream from the coast. The reduction of downward mixing of momentum by the stratification leads to smaller roughness lengths compared to the unstable case. Shear generation at higher levels and advection of stronger turbulence from land often lead to an increase of stress and turbulence energy with height and downward transport of turbulence energy toward the surface.With flow of cool air over a warmer sea surface, a convective internal boundary layer develops downstream from the coast. An overlying relatively thick layer of downward buoyancy flux (virtual temperature flux) is sometimes maintained by shear generation in the accelerating offshore flow.     

Stable Boundary-Layer Scaling Regimes: The Sheba Data

Turbulent and mean meteorological data collected at five levels on a 20-m tower over the Arctic pack ice during the Surface Heat Budget of the Arctic Ocean experiment (SHEBA) are analyzed to examine different regimes of the stable boundary layer (SBL). Eleven months of measurements during SHEBA cover a wide range of stability conditions, from the weakly unstable regime to very stable stratification. Scaling arguments and our analysis show that the SBL can be classified into four major regimes: (i) surface-layer scaling regime (weakly stable case), (ii) transition regime, (iii) turbulent Ekman layer, and (iv) intermittently turbulent Ekman layer (supercritical stable regime). These four regimes may be considered as the basic states of the traditional SBL. Sometimes these regimes, especially the last two, can be markedly perturbed by gravity waves, detached elevated turbulence (‘upside down SBL’), and inertial oscillations. Traditional Monin–Obukhov similarity theory works well in the weakly stable regime. In the transition regime, Businger–Dyer formulations work if scaling variables are re-defined in terms of local fluxes, although stability function estimates expressed in these terms include more scatter compared to the surface-layer scaling. As stability increases, the near-surface turbulence is affected by the turning effects of the Coriolis force (the turbulent Ekman layer). In this regime, the surface layer, where the turbulence is continuous, may be very shallow (< 5 m). Turbulent transfer near the critical Richardson number is characterized by small but still significant heat flux and negligible stress. The supercritical stable regime, where the Richardson number exceeds a critical value, is associated with collapsed turbulence and the strong influence of the earth’s rotation even near the surface. In the limit of very strong stability, the stress is no longer a primary scaling parameter.