Hurricane track trends and environmental flow patterns under surface temperature changes and roughness length variations

IF 6.1 1区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES
Oussama Romdhani, Leo Matak, Mostafa Momen
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引用次数: 0

Abstract

Given the significant damage that hurricanes can cause every year, accurate forecasts of these extreme weather events are crucial. Ocean warming can substantially impact the intensity and track of hurricanes in the future. Forecasting the track of hurricanes is typically more challenging than intensity predictions since tracks are influenced not only by hurricane vortex dynamics but also by global and synoptic weather systems (i.e., environmental flow). The dynamical mechanisms that modulate hurricane trajectories under changes in the surface temperature and friction are not comprehensively established yet. The primary objective of this paper is to address this knowledge gap by conducting six real hurricanes and some non-hurricane simulations using the Weather Research and Forecasting (WRF) model. In total, 90 WRF simulations are carried out to characterize the impacts of varying the surface temperature and drag on hurricane tracks and their relationship with environmental flow patterns. It is found that ocean warming tends to intensify hurricanes by ∼20 % and decrease their azimuthal translational velocity, and vice versa when the surface is cooled. Hurricanes move more towards the west over the Atlantic Ocean when the surface temperature is decreased and vice versa. This was shown to be due to the changes in the average azimuthal speed of environmental flows. Increasing the surface temperature, destabilizes the atmosphere, and increases the surface friction velocity. Hence, increased surface friction appears to slow down the environmental flow and consequently hurricane track azimuthal translational speed. This finding was confirmed by another suite of simulations in which only the surface roughness length of the low-wind environmental flow regime was altered. It was shown that surface drag changes have a similar impact on hurricane tracks as surface temperature variations. Decreasing the default surface drag for low-wind regimes tends to further move the hurricanes toward the west and vice versa. This paper provides notable insights into future hurricane track trends and the role of ocean temperature and momentum exchange coefficients in hurricane track and environmental flow patterns. Moreover, the results of this study can be useful for advancing surface layer parameterizations and their impacts on hurricane track forecasts in weather/climate models.

飓风跟踪表面温度变化和粗糙度长度变化下的趋势和环境流动模式
鉴于飓风每年都会造成重大损失,准确预测这些极端天气事件至关重要。海洋变暖会对未来飓风的强度和路径产生重大影响。飓风路径的预测通常比强度预测更具挑战性,因为路径不仅受到飓风涡旋动力学的影响,还受到全球和同步天气系统(即环境流)的影响。在地表温度和摩擦力变化的情况下调节飓风轨迹的动力学机制尚未全面建立。本文的主要目的是利用天气和研究预报(WRF)模型进行六次真实飓风和一些非飓风模拟,以弥补这一知识空白。总共进行了 90 次 WRF 模拟,以确定改变表面温度和阻力对飓风路径的影响及其与环境流动模式的关系。研究发现,海洋变暖会使飓风增强 20%,并降低其方位平移速度,反之亦然。当表面温度降低时,飓风在大西洋上空更多地向西移动,反之亦然。这是因为环境流的平均方位角速度发生了变化。地表温度升高会破坏大气层的稳定,增加地表摩擦速度。因此,表面摩擦力的增加似乎会减慢环境流的速度,从而减慢飓风轨道的方位角平移速度。另一套模拟证实了这一发现,在这套模拟中,只改变了低风速环境流机制的表面粗糙度长度。结果表明,表面阻力变化对飓风航迹的影响与表面温度变化类似。降低低风速环境下的默认表面阻力往往会使飓风进一步向西移动,反之亦然。本文对未来飓风路径趋势以及海洋温度和动量交换系数在飓风路径和环境流动模式中的作用提供了重要见解。此外,这项研究的结果还有助于推进天气/气候模式中的表层参数化及其对飓风路径预报的影响。
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
Weather and Climate Extremes
Weather and Climate Extremes Earth and Planetary Sciences-Atmospheric Science
CiteScore
11.00
自引率
7.50%
发文量
102
审稿时长
33 weeks
期刊介绍: Weather and Climate Extremes Target Audience: Academics Decision makers International development agencies Non-governmental organizations (NGOs) Civil society Focus Areas: Research in weather and climate extremes Monitoring and early warning systems Assessment of vulnerability and impacts Developing and implementing intervention policies Effective risk management and adaptation practices Engagement of local communities in adopting coping strategies Information and communication strategies tailored to local and regional needs and circumstances
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