重新思考粗糙度高度:短植被温度曲线的改进描述

IF 2.3 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES Boundary-Layer Meteorology Pub Date : 2024-06-21 DOI:10.1007/s10546-024-00871-z
Judith Boekee, Steven J. A. van der Linden, Marie-Claire ten Veldhuis, Iris E. A. Verouden, Paul J. Nollen, Yi Dai, Harro J. Jongen, Bas J. H. van de Wiel
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引用次数: 0

摘要

在这项研究中,我们提出了短植被上粗糙度子层(RSL)的莫宁-奥布科夫相似性理论(MOST)的扩展。我们利用阵列形装置中光缆的温度测量来检验我们的理论。这提供了较高的垂直测量分辨率,使我们能够测量近地表的急剧温度梯度。众所周知,MOST 在 RSL 中是无效的,因为气流会被粗糙度元素扭曲。然而,为了得出表面温度,通常的做法是通过 RSL 向下推断表面的对数剖面。我们的观测结果显示,表面附近的温度曲线接近线性,而不是 MOST 所定义的对数行为。经典湍流文献中的范-德里斯特方程描述了空气动力学光滑表面上的这种对数到线性的转变。在这里,我们提出范-德里斯特方程也可以用来描述粗糙表面上的这种转变,方法是用表面长度尺度 \(L_s\)代替粘性长度尺度,它代表了草结构附近最小涡流的大小。我们的研究表明,\(L_s\) 与植被的几何形状成比例关系,而且该模型有可能扩展到高大的树冠。在描述地表附近的温度曲线和预测地表温度方面,改编后的 Van Driest 模型优于粗糙度长度概念。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Rethinking the Roughness Height: An Improved Description of Temperature Profiles over Short Vegetation

In this study, we present an extension to the Monin–Obukov similarity theory (MOST) for the roughness sublayer (RSL) over short vegetation. We test our theory using temperature measurements from fiber optic cables in an array-shaped set-up. This provides a high vertical measurement resolution that enables us to measure the sharp temperature gradients near the surface. It is well-known that MOST is invalid in the RSL as the flow is distorted by roughness elements. However, to derive the surface temperature, it is common practice to extrapolate the logarithmic profiles down to the surface through the RSL. Instead of logarithmic behaviour defined by MOST near the surface, our observations show near-linear temperature profiles. This log-to-linear transition is described over an aerodynamically smooth surface by the Van Driest equation in classical turbulence literature. Here we propose that the Van Driest equation can also be used to describe this transition over a rough surface, by replacing the viscous length scale with a surface length scale \(L_s\) that represents the size of the smallest eddies near the grass structures. We show that \(L_s\) scales with the geometry of the vegetation and that the model shows the potential to be scaled up to tall canopies. The adapted Van Driest model outperforms the roughness length concept in describing the temperature profiles near the surface and predicting the surface temperature.

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来源期刊
Boundary-Layer Meteorology
Boundary-Layer Meteorology 地学-气象与大气科学
CiteScore
7.50
自引率
14.00%
发文量
72
审稿时长
12 months
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’.
期刊最新文献
Geostrophic Drag Law in Conventionally Neutral Atmospheric Boundary Layer: Simplified Parametrization and Numerical Validation Variation in Zero Plane Displacement and Roughness Length for Momentum Revisited Rainfall Effects on Atmospheric Turbulence and Near-Surface Similarities in the Stable Boundary Layer Rethinking the Roughness Height: An Improved Description of Temperature Profiles over Short Vegetation On the Extent of Applicability of Various Non-linear Similarity Functions for Computation of Surface Fluxes under Stable Conditions in Numerical Models
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