The Roles of Moat Width and Outer Eyewall Contraction in Affecting the Timescale of Eyewall Replacement Cycle

IF 3.8 2区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES Journal of Geophysical Research: Atmospheres Pub Date : 2024-10-07 DOI:10.1029/2024JD041488
Jie Jiang, Yuqing Wang
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Abstract

The timescale of eyewall replacement cycle (ERC) is critical for the prediction of intensity and structure changes of tropical cyclones (TCs) with concentric eyewall (CE) structures. Previous studies have indicated that the moat width can regulate the interaction between the inner and outer eyewalls and has a salient relationship with the ERC timescale. In this study, a series of sensitivity experiments are carried out to investigate the essential mechanisms resulting in the diversity of the duration of CEs using both simple and full-physics models. Results reveal that a larger moat can induce stronger inflow under the same inner eyewall intensity by providing a longer distance for air parcels to accelerate in the boundary layer. Thus, there is greater inward absolute vorticity flux to sustain the inner eyewall. Besides, the equivalent potential temperature (θe) budget indicates that the vertical advection and surface flux of moist entropy can overbalance the negative contribution from the horizontal advection and lead to an increasing trend of θe in the inner eyewall. This suggests that the thermodynamic process in the boundary layer is not indispensable to the inner eyewall weakening. It is also found that the contraction rate of the secondary eyewall, which directly influences the moat width, is subject to the activity of outer spiral rainbands. By directly introducing positive wind tendency outside the eyewall and indirectly promoting a vertically tilted eyewall structure, active convection in the outer region will impede or even suspend the contraction of the outer eyewall and hence extend the ERC timescale.

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护壕宽度和外眼墙收缩在影响眼墙更换周期中的作用
眼球替换周期(ERC)的时间尺度对于预测具有同心眼球(CE)结构的热带气旋(TC)的强度和结构变化至关重要。以往的研究表明,堑壕宽度可以调节内外眼墙之间的相互作用,并与ERC时间尺度有显著关系。在本研究中,利用简单模型和全物理模型进行了一系列敏感性实验,以研究导致 CE 持续时间多样性的基本机制。结果表明,在相同的内眼墙强度下,较大的护城河可为气团提供更长的边界层加速距离,从而诱发更强的流入。因此,有更大的内向绝对涡度通量来维持内眼墙。此外,等效势温(θe)预算表明,湿熵的垂直平流和表面通量可以抵消水平平流的负作用,并导致内侧眼墙的θe呈上升趋势。这表明边界层的热力学过程对内眼墙的减弱并非不可或缺。研究还发现,直接影响护城河宽度的次级眼墙收缩率受制于外螺旋雨带的活动。通过直接在眼墙外引入正风趋势和间接促进垂直倾斜的眼墙结构,外部区域的活跃对流将阻碍甚至暂停外眼墙的收缩,从而延长 ERC 时间尺度。
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来源期刊
Journal of Geophysical Research: Atmospheres
Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics
CiteScore
7.30
自引率
11.40%
发文量
684
期刊介绍: JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.
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