The meteorological drivers of mass coral bleaching on the central Great Barrier Reef during the 2022 La Niña.

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2024-10-12 DOI:10.1038/s41598-024-74181-2

Lara Shania Richards, Steven Thomas Siems, Yi Huang, Wenhui Zhao, Daniel Patrick Harrison, Michael John Manton, Michael John Reeder

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Abstract

The frequencies of marine heatwaves and thermal coral bleaching events (CBEs) over the Great Barrier Reef (GBR) continue to increase with five mass CBEs reported since 2016. While changes in the local meteorology, such as reduced wind speeds and decreased cloud cover, are known to heat the shallow reef waters, little consideration has been given to the overriding synoptic meteorology. The 2022 CBE, occurring under La Niña conditions, saw ocean temperatures at Davies Reef increase 1.9 $^{\circ} C$ over 19-days and subsequently cool 2.1 $^{\circ} C$ back to seasonal norms over eight days. This event was found to be triggered by repeated Rossby wave breaking disrupting the local trade winds, thus inhibiting the latent heat flux. Latent heat fluxes, the primary driver of the event, tripled as the trade winds returned via rapid coastal ridging. These same synoptic features are concurrent with the historic Lismore flooding located hundreds of kilometres south of the GBR.

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2022 年拉尼娜现象期间大堡礁中部大规模珊瑚白化的气象驱动因素。

大堡礁（GBR）上空的海洋热浪和热珊瑚白化事件（CBEs）的频率持续上升，自 2016 年以来已报告了五次大规模 CBEs。众所周知，当地气象的变化（如风速降低和云量减少）会使浅礁水域升温，但人们却很少考虑压倒一切的同步气象。2022 年的 CBE 发生在拉尼娜条件下，戴维斯礁的海洋温度在 19 天内上升了 1.9 ∘ C，随后又在 8 天内下降了 2.1 ∘ C，回到了季节性标准。研究发现，这一事件是由于反复出现的罗斯比波扰乱了当地信风，从而抑制了潜热通量。潜热通量是这次事件的主要驱动力，当信风通过快速的沿岸隆起恢复时，潜热通量增加了两倍。这些同步特征与位于英国大堡礁以南数百公里处的利斯莫尔历史性洪水同时出现。

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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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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