Adequately reflecting the severity of tropical cyclones using the new Tropical Cyclone Severity Scale

Bloemendaal, Nadia; Moel, Hans de; Mol, Jantsje M.; Bosma, Priscilla R M; Polen, Amy; Collins, Jennifer

doi:10.1088/1748-9326/abd131

Cited by 21 publications

(12 citation statements)

References 37 publications

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“…These high intensity winds (>75 m/s) resulted on average in a reduction in NDVI greater than 40%. While this breakpoint relies only on a few points, it feeds the debate about updating TC intensity scales to better fit increasing TC intensity (e.g., [27,28]). Indeed, such extremely intense TCs occurred during the last decade and may reflect the possible intensification of these disturbances under human-induced global warming (e.g., [10,29]).…”

Section: Discussionmentioning

confidence: 99%

Tropical Cyclone Impact and Forest Resilience in the Southwestern Pacific

et al. 2022

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Tropical cyclones (TCs) can have profound effects on the dynamics of forest vegetation that need to be better understood. Here, we analysed changes in forest vegetation induced by TCs using the normalized difference vegetation index (NDVI). We used an accurate historical database of TC tracks and intensities, together with the Willoughby cyclone model to reconstruct the 2D surface wind speed structure of TCs and analyse how TCs affect forest vegetation. We used segmented linear models to identify significant breakpoints in the relationship between the reconstructed maximum sustained wind speed (Wmax) and the observed changes in NDVI. We tested the hypothesis that the rate of change in damage caused by TCs to forest and recovery time would increase according to Wmax thresholds as defined in the widely used Saffir–Simpson hurricane wind scale (SSHWS). We showed that the most significant breakpoint was located at 50 m/s. This breakpoint corresponds to the transition between categories 2 and 3 TCs in the SSHWS. Below this breakpoint, damages caused to forest vegetation and the time needed to recover from these damages were negligable. We found a second breakpoint, with a sharp increase in damages for winds >75 m/s. This suggested that extremely intense tropical cyclones, which might be more frequent in the future, can cause extreme damages to forest vegetation. Nevertheless, we found high variation in the observed damages and time needed to recover for a given Wmax. Further studies are needed to integrate other factors that might affect the exposure and resistance to TCs as well as forests’ capacity to recover from these disturbances.

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Section: Discussionmentioning

confidence: 99%

Tropical Cyclone Impact and Forest Resilience in the Southwestern Pacific

et al. 2022

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“…Ample documentation of the event permits result validation and provides a reality check on quality and information content of the developed model. Further, Michael's severity was dominated by strong winds and storm surge as opposed to torrential rainfalls [61]. The hazard can therefore be approximated by modelling only its wind-field, lending itself as an illustrative, yet simple enough example.…”

Section: Application: CI Failures and Basic Service Disruptions From ...mentioning

confidence: 99%

A Generalized Natural Hazard Risk Modelling Framework for Infrastructure Failure Cascades

Mühlhofer¹,

Koks²,

Kropf³

et al. 2022

Preprint

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Critical infrastructures are more exposed than ever to natural hazards in a chaning climate. To understand and manage risk, failure cascades across large, real-world infrastructure networks, caused by real-world hazards, and their impact on people, must be captured. Bridging established methods in both infrastructure and risk modelling communities, we develop an open-source modelling framework which integrates a network-based interdependent infrastructure system model into the globally consistent and spatially explicit natural hazard risk assessment platform CLIMADA. The model captures infrastructure damages, triggers failure cascades and estimates resulting basic service disruptions for the dependent population. It flexibly operates on large areas with publicly available hazard, exposure and vulnerability information, for any infrastructure networks, hazards and geographies of interest. In a validated case study for 2018’s Hurricane Michael across three US states, the model reproduced important failure dynamics among six infrastructure networks, and provided a novel spatial map of where people were likely to experience disruptions in access to healthcare, loss of power and other vital services. Our generalized approach allows for a view on infrastructure risks and their social impacts also in areas where detailed information and risk assessments are traditionally scarce, informing humanitarian activities through hotspot analyses and policy frameworks alike.

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“…While the Saffir-Simpson category scale is routinely used to communicate to the public the imminent danger posed by tropical cyclones, more comprehensive alternative scales have been proposed but not widely adopted [26][27][28]. While interpreted by the impact of selected damage types, the Saffir-Simpson scale is actually defined by 1 min average peak near surface wind exceedances over fixed thresholds.…”

Section: Introductionmentioning

confidence: 99%

Simulated Changes in Tropical Cyclone Size, Accumulated Cyclone Energy and Power Dissipation Index in a Warmer Climate

Wehner

2021

Oceans

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Detection, attribution and projection of changes in tropical cyclone intensity statistics are made difficult from the potentially decreasing overall storm frequency combined with increases in the peak winds of the most intense storms as the climate warms. Multi-decadal simulations of stabilized climate scenarios from a high-resolution tropical cyclone permitting atmospheric general circulation model are used to examine simulated global changes from warmer temperatures, if any, in estimates of tropical cyclone size, accumulated cyclonic energy and power dissipation index. Changes in these metrics are found to be complicated functions of storm categorization and global averages of them are unlikely to easily reveal the impact of climate change on future tropical cyclone intensity statistics.

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Adequately reflecting the severity of tropical cyclones using the new Tropical Cyclone Severity Scale

Cited by 21 publications

References 37 publications

Tropical Cyclone Impact and Forest Resilience in the Southwestern Pacific

Tropical Cyclone Impact and Forest Resilience in the Southwestern Pacific

A Generalized Natural Hazard Risk Modelling Framework for Infrastructure Failure Cascades

Simulated Changes in Tropical Cyclone Size, Accumulated Cyclone Energy and Power Dissipation Index in a Warmer Climate

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