More Like this

1. Heavier Inner-core Rainfall of Major Hurricanes in the North Atlantic Basin than Other Global Basins

   https://doi.org/10.1175/JCLI-D-20-0668.1  

   Guzman, Oscar; Jiang, Haiyan (April 2021, Journal of Climate)

   Abstract Based on 19 years of precipitation data collected by the Tropical Rainfall Measuring Mission (TRMM) and the Global Precipitation Measurement (GPM) mission, a comparison of the rainfall produced by tropical cyclones (TCs) in different global basins is presented. A total of 1789 TCs were examined in the period from 1998 to 2016 by taking advantage of more than 47,737 observations of TRMM/GPM 3B42 multi-satellite derived rainfall amounts. The axisymmetric component of the TC rainfall is analyzed in all TC-prone basins. The resulting radial profiles show that major hurricanes in the Atlantic basin exhibit significantly heavier inner-core rainfall rates than those in any other basins. To explain the possible causes of this difference, rainfall distributions for major hurricanes are stratified according to different TC intensity and environmental variables. Based on the examination of these parameters, we found that the stronger rainfall rates in the Atlantic major hurricanes are associated with higher values of convective available potential energy, drier relative humidity in the low to middle troposphere, colder air temperature at 250hPa, and stronger vertical wind shear than other basins. These results have important implications in the refining of our understanding of the mechanisms of TC rainfall. 

   more » « less
2. Climatology of Tropical Cyclone Rainfall Magnitude at Different Landfalling Stages: An Emphasis on After-Landfall Rain

   https://doi.org/10.1175/JAMC-D-22-0055.1  

   Guzman, Oscar; Jiang, Haiyan (July 2023, Journal of Applied Meteorology and Climatology)

   Abstract Estimating the magnitude of tropical cyclone (TC) rainfall at different landfalling stages is an important aspect of the TC forecast that directly affects the level of response from emergency managers. In this study, a climatology of the TC rainfall magnitude as a function of the location of the TC centers within distance intervals from the coast and the percentage of the raining area over the land is presented on a global scale. A total of 1834 TCs in the period from 2000 until 2019 are analyzed using satellite information to characterize the precipitation magnitude, volumetric rain, rainfall area, and axial-symmetric properties within the proposed landfalling categories, with an emphasis on the postlandfall stages. We found that TCs experience rainfall maxima in regions adjacent to the coast when more than 50% of their rainfall area is over the water. TC rainfall is also analyzed over the entire TC extent and the portion over land. When the total extent is considered, rainfall intensity, volumetric rain, and rainfall area increase with wind speed intensity. However, once it is quantified over the land only, we found that rainfall intensity exhibits a nearly perfect inversely proportional relation with the increase in TC rainfall area. In addition, when a TC with life maximum intensity of a major hurricane makes landfall as a tropical depression or tropical storm, it usually produces the largest spatial extent and the highest volumetric rain. Significant StatementThis study aims to describe the cycle of tropical cyclone (TC) precipitation magnitude through a new approach that defines the landfall categories as a function of the percentage of the TC precipitating area over the land and ocean, along with the location of the TC centers within distance intervals from the coast. Our central hypothesis is that TC rainfall should exhibit distinct features in the long-term satellite time series for each of the proposed stages. We particularly focused on the overland events due to their effects on human activities, finding that the TCs that at some point of their life cycle reached major hurricane strength and made landfall as a tropical storm or tropical depression produced the highest volumetric rain over the land surface. This research also presents key observational evidence of the relationship between the rain rate, raining area, and volumetric rain for landfalling TCs. 

   more » « less
3. Using high resolution climate models to explore future changes in post-tropical cyclone precipitation

   https://doi.org/10.1088/1748-9326/ad2163  

   Bower, Erica; Reed, Kevin A (February 2024, Environmental Research Letters)

   Abstract One of the most costly effects of climate change will be its impact on extreme weather events, including tropical cyclones (TCs). Understanding these changes is of growing importance, and high resolution global climate models are providing potential for such studies, specifically for TCs. Beyond the difficulties associated with TC behavior in a warming climate, the extratropical transition (ET) of TCs into post-tropical cyclones (PTCs) creates another challenge when understanding these events and any potential future changes. PTCs can produce excessive rainfall despite losing their original tropical characteristics. The present study examines the representation of PTCs and their precipitation in three high resolution (25–50 km) climate models: CNRM, MRI, and HadGEM. All three of these models agree on a simulated decrease in TC and PTC events in the future warming scenario, yet they lack consistency in simulated regional patterns of these changes, which is further evident in regional changes in PTC-related precipitation. The models also struggle with their represented intensity evolution of storms during and after the ET process. Despite these limitations in simulating intensity and regional characteristics, the models all simulate a shift toward more frequent rain rates above 10 mm h⁻¹in PTCs. These high rain rates become 4%–12% more likely in the warmer climate scenario, resulting in a 5%–12% increase in accumulated rainfall from these rates. 

   more » « less
4. Trends in U.S. Atlantic Tropical Cyclone Damage, 1900–2022

   https://doi.org/10.1175/JAMC-D-24-0047.1  

   Willoughby, H E; Hernandez, J I; Pinnock, Andrew (December 2024, Journal of Applied Meteorology and Climatology)

   Qi, Hu (Ed.)

   Abstract A series of papers published since 1998 assert that U.S. tropical cyclone (TC) damage, when “normalized” for individual wealth, population, and inflation, exhibits no increase attributable to anthropogenic global warming (AGW). This result is here questioned for three reasons: 1) The then-year (no demographic or economic adjustments) U.S. TC damage increases 2.5% yr⁻¹faster than U.S. then-year gross domestic product. This result, which is substantially due to the faster growth of assets in hurricane-prone states, shows that TC impacts on the total U.S. economy double every generation. 2) Fitting of an exponential curve to normalized damage binned by 5-yr “pentads” yields a growth rate of 1.06% yr⁻¹since 1900, although causes besides AGW may contribute. 3) During the twenty-first century, when the Atlantic multidecadal oscillation (AMO) was in its warm phase, the most damaging U.S. TCs struck at twice the rate of the warm AMO of the twentieth century and 4 times the rate of the entire twentieth century, both warm and cool AMO phases. A key unanswered question is as follows: What will happen when (and if) the AMO returns to its cool phase later in this century? Significance StatementU.S. hurricane damage, normalized for changes in inflation, population, and wealth, increases by approximately 1% yr⁻¹. For 1900–2022, 1% yr⁻¹is equivalent to a factor of >3 increase, substantially but not entirely, attributable to climate change. The incidence of the most damaging tropical cyclones (TCs) approximately doubled in the twenty-first century compared with climatologically analogous periods of the twentieth century. These results contradict the previously published work that introduced normalization and found zero trend in normalized damage but are consistent with physical reasoning and modeling studies. 

   more » « less
5. Tropical cyclone climatology change greatly exacerbates US extreme rainfall–surge hazard

   https://doi.org/10.1038/s41558-021-01272-7  

   Gori, Avantika; Lin, Ning; Xi, Dazhi; Emanuel, Kerry (February 2022, Nature Climate Change)

   Abstract Tropical cyclones (TCs) are drivers of extreme rainfall and surge, but the current and future TC rainfall–surge joint hazard has not been well quantified. Using a physics-based approach to simulate TC rainfall and storm tides, we show drastic increases in the joint hazard from historical to projected future (SSP5–8.5) conditions. The frequency of joint extreme events (exceeding both hazards’ historical 100-year levels) may increase by 7–36-fold in the southern US and 30–195-fold in the Northeast by 2100. This increase in joint hazard is induced by sea-level rise and TC climatology change; the relative contribution of TC climatology change is higher than that of sea-level rise for 96% of the coast, largely due to rainfall increases. Increasing storm intensity and decreasing translation speed are the main TC change factors that cause higher rainfall and storm tides and up to 25% increase in their dependence. 

   more » « less