{"title":"Understanding Meteorological Changes Following Severe Defoliation During a Strong Hurricane Landfall: Insights from Hurricane Michael (2018)","authors":"Shannon A. Nelson, P. Miller","doi":"10.1175/ei-d-22-0012.1","DOIUrl":null,"url":null,"abstract":"\nDespite prompting persistent meteorological changes, severe defoliation following a tropical cyclone (TC) landfall has received relatively little attention and is largely overlooked within hurricane preparedness and recovery planning. Changes to near-track vegetation can modify evapotranspiration for months after tropical cyclone passage, thereby altering boundary layer moisture and energy fluxes that drive the local water cycle. This study seeks to understand potential spatial and temporal changes in defoliation-driven meteorological conditions using Hurricane Michael (2018) as a testbed. In this sensitivity study, two Weather Research and Forecasting (WRF) model simulations, a normal-landscape and a post-TC scenario, are compared to determine how a defoliation scar placed along Michael’s path alters surface heat fluxes, temperature, relative humidity, and precipitation near the storm’s track.\nIn the month following the foliage reduction, WRF resolves a 0.7°C 2-m temperature increase with the greatest changes occurring at night. Meanwhile, the simulations produce changes to the sensible and latent heat fluxes of +8.3 W m−2 and −13.9 W m−2, respectively, while average relative humidity decreased from 73% to 70.1%. Though the accumulated precipitation in the defoliated simulation was larger along a narrow corridor paralleling and downwind of the hurricane track, neither simulation satisfactorily replicated post-Michael precipitation patterns as recorded by NCEP Stage IV QPE, casting doubt as to whether the downwind enhancement was exclusively due to the defoliation scar. This sensitivity analysis provides insight to the types of changes that may be possible following rapid and widespread defoliation during a TC landfall.","PeriodicalId":51020,"journal":{"name":"Earth Interactions","volume":null,"pages":null},"PeriodicalIF":1.6000,"publicationDate":"2023-01-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Earth Interactions","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1175/ei-d-22-0012.1","RegionNum":4,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"GEOSCIENCES, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 1
Abstract
Despite prompting persistent meteorological changes, severe defoliation following a tropical cyclone (TC) landfall has received relatively little attention and is largely overlooked within hurricane preparedness and recovery planning. Changes to near-track vegetation can modify evapotranspiration for months after tropical cyclone passage, thereby altering boundary layer moisture and energy fluxes that drive the local water cycle. This study seeks to understand potential spatial and temporal changes in defoliation-driven meteorological conditions using Hurricane Michael (2018) as a testbed. In this sensitivity study, two Weather Research and Forecasting (WRF) model simulations, a normal-landscape and a post-TC scenario, are compared to determine how a defoliation scar placed along Michael’s path alters surface heat fluxes, temperature, relative humidity, and precipitation near the storm’s track.
In the month following the foliage reduction, WRF resolves a 0.7°C 2-m temperature increase with the greatest changes occurring at night. Meanwhile, the simulations produce changes to the sensible and latent heat fluxes of +8.3 W m−2 and −13.9 W m−2, respectively, while average relative humidity decreased from 73% to 70.1%. Though the accumulated precipitation in the defoliated simulation was larger along a narrow corridor paralleling and downwind of the hurricane track, neither simulation satisfactorily replicated post-Michael precipitation patterns as recorded by NCEP Stage IV QPE, casting doubt as to whether the downwind enhancement was exclusively due to the defoliation scar. This sensitivity analysis provides insight to the types of changes that may be possible following rapid and widespread defoliation during a TC landfall.
尽管引发了持续的气象变化,热带气旋(TC)登陆后的严重落叶却很少受到关注,而且在飓风准备和恢复计划中很大程度上被忽视。热带气旋通过后,近轨道植被的变化可以改变几个月的蒸散,从而改变驱动当地水循环的边界层水分和能量通量。本研究试图以飓风迈克尔(2018)为实验平台,了解落叶驱动的气象条件的潜在时空变化。在这项敏感性研究中,比较了两个天气研究与预报(WRF)模型的模拟,一个是正常景观,一个是后tc情景,以确定沿着迈克尔路径放置的落叶疤痕如何改变风暴路径附近的地表热通量、温度、相对湿度和降水。在落叶减少后的一个月里,WRF解析出0.7°C的2米温度升高,其中最大的变化发生在夜间。与此同时,模拟结果显示,+8.3 W m−2和- 13.9 W m−2的感热通量和潜热通量发生了变化,平均相对湿度从73%下降到70.1%。虽然在飓风路径平行和下风的狭窄走廊上,落叶模拟的累积降水更大,但两种模拟都不能令人满意地复制NCEP第四阶段QPE记录的后michael降水模式,这让人怀疑下风增强是否完全是由于落叶疤痕造成的。这种敏感性分析提供了对TC登陆期间快速和广泛落叶后可能发生的变化类型的见解。
期刊介绍:
Publishes research on the interactions among the atmosphere, hydrosphere, biosphere, cryosphere, and lithosphere, including, but not limited to, research on human impacts, such as land cover change, irrigation, dams/reservoirs, urbanization, pollution, and landslides. Earth Interactions is a joint publication of the American Meteorological Society, American Geophysical Union, and American Association of Geographers.