Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Molinari, John; Zhang, Jun A.; Rogers, Robert F.; Vollaro, David

doi:10.1175/mwr-d-18-0345.1

Cited by 12 publications

(8 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Because tropical cyclone (TC) intensity is influenced by multiple factors spanning different spatiotemporal scales (Marks et al 1998, Rogers et al 2006Dougherty et al 2018), our investigation is based on four aspects: 1) large-scale atmospheric environment, e.g. VWS and relative humidity (RH) (De Maria et al 2005;Knaff et al 2005;2018; Kaplan et al 2010;; 2) large-scale pre-TC ocean environment and local-scale, during-TC air-sea interactions, e.g., pre-TC Sea Surface Temperature (SST), pre-TC Ocean Heat Content (OHC), TC's self-induced ocean cooling effect (during-TC), and the during-TC air-sea fluxes (Shay et al 2000;Cione and Uhlhorn 2003;Lin et al 2008Lin et al , 2013Goni et al 2009;Cione 2015;Jaimes et al 2015;Tsuboki et al 2015;Zhang et al 2017;Chih and Wu 2020); 3) vortex-scale properties, e.g., storm size, translation speed (Uh), and ERCs (Chavas and Emanuel 2010;Chan and Chan 2012;Knaff et al 2016;Molinari et al 2019;Shen et al 2021); and 4) convective-scale features, e.g., radial location of deep convection (Rogers 2010;Rogers et al 2013Rogers et al , 2015Rogers et al , 2016Miyamoto and Takemi 2015;Kanada et al 2017;Hu and Wu 2020;Peng and Wu 2020). For observations, atmospheric environmental data is from the US National Centers for Environmental Prediction Climate Forecast System Reanalysis (NCEP CFSR-V2, 6-hrly/1∘data).…”

Section: Methodsmentioning

confidence: 99%

A Tale of Two Rapidly Intensifying Supertyphoons: Hagibis (2019) and Haiyan (2013)

Lin

Rogers

Huang

et al. 2021

Bulletin of the American Meteorological Society

Self Cite

View full text Add to dashboard Cite

Devastating Japan in October 2019, Supertyphoon (STY) Hagibis was an important typhoon in the history of the Pacific. A striking feature of Hagibis was its explosive RI (rapid intensification). In 24 h, Hagibis intensified by 100 kt, making it one of the fastest-intensifying typhoons ever observed. After RI, Hagibis’s intensification stalled. Using the current typhoon intensity record holder, i.e., STY Haiyan (2013), as a benchmark, this work explores the intensity evolution differences of these 2 high-impact STYs.We found that the extremely high pre-storm sea surface temperature reaching 30.5°C, deep/warm pre-storm ocean heat content reaching 160 kJ cm−2, fast forward storm motion of ~8 ms−1, small during-storm ocean cooling effect of ~ 0.5C, significant thunderstorm activity at its center, and rapid eyewall contraction were all important contributors to Hagibis’s impressive intensification. There was 36% more air-sea flux for Hagibis’s RI than for Haiyan’s.After its spectacular RI, Hagibis’s intensification stopped, despite favorable environments. Haiyan, by contrast, continued to intensify, reaching its record-breaking intensity of 170 kt. A key finding here is the multiple pathways that storm size affected the intensity evolution for both typhoons. After RI, Hagibis experienced a major size expansion, becoming the largest typhoon on record in the Pacific. This size enlargement, combined with a reduction in storm translational speed, induced stronger ocean cooling that reduced ocean flux and hindered intensification. The large storm size also contributed to slower eyewall replacement cycles (ERCs), which prolonged the negative impact of the ERC on intensification.

show abstract

Section: Methodsmentioning

confidence: 99%

A Tale of Two Rapidly Intensifying Supertyphoons: Hagibis (2019) and Haiyan (2013)

Lin

Rogers

Huang

et al. 2021

Bulletin of the American Meteorological Society

Self Cite

View full text Add to dashboard Cite

show abstract

“…During 6hr‐long precipitation pulse events, the precipitation signal only translates 300 km outward, but the cloud top cooling signature propagates at least 500 km away. On the other hand, less than 20% (561) of the precipitation pulses occur in the absence of cold‐cloud pulse, which may be partially associated with the eyewall replacement cycles or rainband activity (Fischer et al., 2020; Molinari et al., 2019; Sitkowski et al., 2012).…”

Section: Resultsmentioning

confidence: 99%

Is There an Outward Propagating Diurnal Signal in the Precipitation of Tropical Cyclones?

Zhang

2022

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

“…While TCs typically weaken during ERCs, recent work has found that in some cases the TC will fail to weaken as the ERC completes (Dougherty et al 2018), or even rapidly intensify (Fischer et al 2020). The variability of the temporal scales of ERCs has also been noted, as the duration of an ERC can range from less than 12 h to multiple days (Molinari et al 2019;Fischer et al 2020). Furthermore, the nature of TC convective asymmetries during ERCs has been assessed (Didlake et al 2017;Dougherty et al 2018;Didlake et al 2018;Fischer et al 2020).…”

Section: Secondary Eyewall Formation and Eyewall Replacement Cyclesmentioning

confidence: 99%

Accomplishments of NOAA’s Airborne Hurricane Field Program and a Broader Future Approach to Forecast Improvement

Zawislak

Rogers

Aberson

et al. 2022

Bulletin of the American Meteorological Society

Self Cite

View full text Add to dashboard Cite

Since 2005, NOAA has conducted the annual Intensity Forecasting Experiment (IFEX), led by scientists from the Hurricane Research Division at NOAA’s Atlantic Oceanographic andMeteorological Laboratory. They partner with NOAA’s Aircraft Operations Center, who maintain and operate the WP-3D and G-IV Hurricane Hunter aircraft, and NCEP’s National Hurricane Center and Environmental Modeling Center, who task airborne missions to gather data used by forecasters for analysis and forecasting and for ingest into operational numerical weather prediction models. The goal of IFEX is to improve tropical cyclone (TC) forecasts using an integrated approach of analyzing observations from aircraft, initializing and evaluating forecast models with those observations, and developing new airborne instrumentation and observing strategies targeted at filling observing gaps and maximizing the data’s impact in model forecasts. This summary article not only highlights recent IFEX contributions towards improved TC understanding and prediction, but also reflects more broadly on the accomplishments of the program during the 16 years of its existence. It describes how IFEX addresses high-priority forecast challenges, summarizes recent collaborations, describes advancements in observing systems monitoring structure and intensity, as well as in assimilation of aircraft data into operational models, and emphasizes key advances in understanding of TC processes, particularly those that lead to rapid intensification. The article concludes by laying the foundation for the “next generation” of IFEX as it broadens its scope to all TC hazards, particularly rainfall, storm-surge inundation, and tornadoes, that have gained notoriety during the last few years after several devastating landfalling TCs.

show abstract

Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Cited by 12 publications

References 43 publications

A Tale of Two Rapidly Intensifying Supertyphoons: Hagibis (2019) and Haiyan (2013)

A Tale of Two Rapidly Intensifying Supertyphoons: Hagibis (2019) and Haiyan (2013)

Is There an Outward Propagating Diurnal Signal in the Precipitation of Tropical Cyclones?

Accomplishments of NOAA’s Airborne Hurricane Field Program and a Broader Future Approach to Forecast Improvement

Contact Info

Product

Resources

About