Laura Mack, Terje Koren Berntsen, Nikki Vercauteren, Norbert Pirk
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The site exhibits a bimodal topography-following flux footprint, with the two dominant wind sectors characterized by organized and strongly negative momentum flux, but different anisotropy and contributions of submeso-scale motions, leading to a failure of eddy-diffusivity closures and different transfer efficiencies for different scalars. The quadrant analysis of the momentum flux reveals that under stable conditions sweeps transport more momentum than the more frequently occurring ejections, while the opposite is observed under unstable stratification. From quadrant analysis, we derive the ratio of the amount of disorganized to organized structures, that we refer to as organization ratio (OR). We find an invertible relation between transfer efficiency and corresponding organization ratio with an algebraic sigmoid function. The organization ratio further explains the scatter around scaling functions used in MOST and thus indicates that coherent structures modify MOST. 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引用次数: 0
摘要
大气与地表之间的动量、热量和痕量气体交换主要由湍流通量控制。湍流混合通常使用莫宁-奥布霍夫相似理论(MOST)进行参数化,该理论是针对均质平坦表面上的稳定湍流而推导的,但也经常被应用于非均质表面上的非稳定湍流。我们研究了在挪威芬斯一个高度异质的高山峡谷地点进行的四年涡度协方差测量,以深入了解 MOST 的有效性、湍流传输机制和相关结构。该地点呈现出双峰地形跟随通量足迹,两个主导风区的特点是有组织和强烈的负动量通量,但各向异性不同,亚尺度运动的贡献也不同,导致涡度扩散闭合失败,不同标量的传输效率也不同。对动量通量的象限分析表明,在稳定条件下,横扫比频繁发生的喷射传输更多的动量,而在不稳定分层条件下则相反。通过象限分析,我们得出了无组织结构与有组织结构的数量比,我们称之为组织比(OR)。我们发现,转移效率与相应的组织比率之间存在可逆的代数半径函数关系。组织比率进一步解释了 MOST 中使用的缩放函数的分散性,从而表明相干结构对 MOST 起着修饰作用。我们的研究结果凸显了相干结构在异质冻原环境中湍流传输中的关键作用,可能有助于为数值天气预报或气候模型找到新的参数。
Transfer Efficiency and Organization in Turbulent Transport over Alpine Tundra.
The exchange of momentum, heat and trace gases between atmosphere and surface is mainly controlled by turbulent fluxes. Turbulent mixing is usually parametrized using Monin-Obukhov similarity theory (MOST), which was derived for steady turbulence over homogeneous and flat surfaces, but is nevertheless routinely applied to unsteady turbulence over non-homogeneous surfaces. We study four years of eddy-covariance measurements at a highly heterogeneous alpine valley site in Finse, Norway, to gain insights into the validity of MOST, the turbulent transport mechanisms and the contributing coherent structures. The site exhibits a bimodal topography-following flux footprint, with the two dominant wind sectors characterized by organized and strongly negative momentum flux, but different anisotropy and contributions of submeso-scale motions, leading to a failure of eddy-diffusivity closures and different transfer efficiencies for different scalars. The quadrant analysis of the momentum flux reveals that under stable conditions sweeps transport more momentum than the more frequently occurring ejections, while the opposite is observed under unstable stratification. From quadrant analysis, we derive the ratio of the amount of disorganized to organized structures, that we refer to as organization ratio (OR). We find an invertible relation between transfer efficiency and corresponding organization ratio with an algebraic sigmoid function. The organization ratio further explains the scatter around scaling functions used in MOST and thus indicates that coherent structures modify MOST. Our results highlight the critical role of coherent structures in turbulent transport in heterogeneous tundra environments and may help to find new parametrizations for numerical weather prediction or climate models.
期刊介绍:
Boundary-Layer Meteorology offers several publishing options: Research Letters, Research Articles, and Notes and Comments. The Research Letters section is designed to allow quick dissemination of new scientific findings, with an initial review period of no longer than one month. The Research Articles section offers traditional scientific papers that present results and interpretations based on substantial research studies or critical reviews of ongoing research. The Notes and Comments section comprises occasional notes and comments on specific topics with no requirement for rapid publication. Research Letters are limited in size to five journal pages, including no more than three figures, and cannot contain supplementary online material; Research Articles are generally fifteen to twenty pages in length with no more than fifteen figures; Notes and Comments are limited to ten journal pages and five figures. Authors submitting Research Letters should include within their cover letter an explanation of the need for rapid publication. More information regarding all publication formats can be found in the recent Editorial ‘Introducing Research Letters to Boundary-Layer Meteorology’.