雲はどんな形をしているのか?(What’s That Cloud Look Like?)

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2024-01-10 パシフィック・ノースウェスト国立研究所(PNNL)

◆米国太平洋北西部国立研究所(PNNL)の研究者は、雲の形状が進化すると予測可能なパターンが現れることを発見しました。コンピュータシミュレーションを使用して、雲の形状が変化するとその端がよりギザギザになり、全体の形状はあまり変わらないことを示しました。
◆この研究は、ギザギザした端を持つ雲が複数の実体に分裂しやすいことを示しています。雲の形状変化における雲端の不規則性の重要性を強調し、気象予報や気候パターンの予測の精度向上に寄与する可能性があります。

<関連情報>

浅い積雲の形状が雲同士の相互作用と雲近傍環境との混合に及ぼす影響 The Effects of Shallow Cumulus Cloud Shape on Interactions Among Clouds and Mixing With Near-Cloud Environments

Jingyi Chen, Samson Hagos, Heng Xiao, Jerome Fast, Chunsong Lu, Adam Varble, Zhe Feng, Jingxi Sun
Geophysical Research Letters  Published: 26 December 2023
DOI:https://doi.org/10.1029/2023GL106334

雲はどんな形をしているのか?(What’s That Cloud Look Like?)

Abstract

Cloud lifecycles are influenced by interactions among clouds and mixing with cloud-free environments. Cloud shapes dictate the length of cloud boundaries, which affects these interactions. This study uses a large eddy simulation to examine the relationships between the shallow cumulus cloud shapes, processes at their boundaries, and lifecycles. To characterize the shape of clouds, two metrics are newly defined: one reflects the overall horizontal cloud shape, and the other defines the cloud edge irregularity. Simulated clouds experience increased irregularity, but little changes in aspect ratio. Irregularity-driven cloud perimeter growth strongly indicates cloud splitting, with a more pronounced effect than aspect ratio-driven perimeter growth. Smaller cloud-shell gradients of properties across cloud boundaries are associated with more irregular clouds, suggesting enhanced mixing of clouds with the cloud-free environment. These findings indicate that the shallow cumulus evolution is partly driven by the irregularity of the cloud edge through lateral mixing and cloud splitting.

Key Points

  • Shallow cumulus clouds develop more irregular edges while maintaining a similar overall shape as they age
  • There is more perimeter growth before clouds split than merge, led by more irregular edges than by changes in overall shape
  • The growth of the cloud perimeter led by irregular edges relates to small differences with nearby clear air attributed to lateral mixing

Plain Language Summary

This study uses computer simulations of small fluffy clouds to examine how the shape of these clouds impacts their evolution. As clouds evolve, their edges become more jagged, but their overall shape does not change much. Clouds with more jagged edges are more likely to split in two. Furthermore, the jaggedness of the cloud edge affects mixing with the surrounding clear air, which influences cloud growth and decay. These findings highlight the importance of irregularity on the edge of the cloud for the evolution of entire clouds.

1702地球物理及び地球化学
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