阿尔蒂普拉诺浅层盐水泻湖上空大气边界层过程驱动的蒸发现象

Francisca Aguirre-Correa, J. Vilà‐Guerau de Arellano, Reinder Ronda, F. Lobos-Roco, Francisco Suárez, O. Hartogensis
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摘要

对阿尔蒂普拉诺盐水泻湖的观测表明,正午时分,当稳定的浅层大气边界层(ABL)过渡到深层混合层时,会引发蒸发(E)。我们利用陆地-大气概念模型、观测数据和区域模型研究了 ABL 和蒸发驱动因素之间的耦合关系。此外,我们还利用适用于海水的彭曼方程分析了 ABL 与蒸发的空气动力和辐射成分之间的相互作用。我们的研究结果表明,非本地过程在驱动 E 方面占主导地位。在早晨,ABL 受本地暖空气(∼5 Kh-1)的平流控制,从而形成浅层(<350 米)、稳定的 ABL,几乎没有混合,也没有 E(<50 Wm-2)。暖空气平流最终将 ABL 与上方的残余层连接起来,使 ABL 高度(h)增加了 ∼1 公里。正午时分,一股由热气流驱动的区域气流到达泻湖,首先从周围的沙漠中平流出更深的 ABL(∼1500 mh-1),导致 ABL 高度(h)额外增加了∼700 m。区域气流还导致风力增大(∼12 ms-1),冷空气(∼-2 Kh-1)进入导致 ABL 崩塌,ABL 变浅(∼-350 mh-1)。风产生的湍流降低了空气动力阻力,并使水体混合,释放出先前储存在湖中的能量。ABL 通过蒸气压对 E 的反馈使蒸发值很高(1430 LT 时为 450 Wm-2)。这些结果有助于了解半干旱条件下的水体蒸发量,并强调了在描述蒸发驱动因素时了解 ABL 过程的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaporation driven by Atmospheric Boundary Layer Processes over a Shallow Salt-Water Lagoon in the Altiplano
Observations over a salt-water lagoon in the Altiplano show that evaporation (E) is triggered at noon, concurrent to the transition of a shallow, stable atmospheric boundary layer (ABL) into a deep mixed layer. We investigate the coupling between the ABL and E drivers using a land-atmosphere conceptual model, observations and a regional model. Additionally, we analyze the ABL interaction with the aerodynamic and radiative components of evaporation using the Penman equation adapted to salt-water. Our results demonstrate that non-local processes are dominant in driving E. In the morning the ABL is controlled by the local advection of warm air (∼5 Kh−1), which results in a shallow (<350 m), stable ABL, with virtually no mixing and no E (<50 Wm−2). The warm-air advection ultimately connects the ABL with the residual layer above, increasing the ABL height (h) by ∼1-km. At midday a thermally-driven regional flow arrives to the lagoon, which first advects a deeper ABL from the surrounding desert (∼1500 mh−1) that leads to an extra ∼700-m h increase. The regional flow also causes an increase in wind (∼12 ms−1) and an ABL collapse due to the entrance of cold air (∼−2 Kh−1) with a shallower ABL (∼−350 mh−1). The turbulence produced by the wind decreases the aerodynamic resistance and mixes the water body releasing the energy previously stored in the lake. The ABL feedback on E through vapor pressure enables high evaporation values (∼450 Wm−2 at 1430 LT). These results contribute to the understanding of E of water bodies in semi-arid conditions and emphasize the importance of understanding ABL processes when describing evaporation drivers.
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