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1. A Comparison of Tropical Cyclone Projections in a High-resolution Global Climate Model and from Downscaling by Statistical and Statistical-deterministic Methods

   https://doi.org/10.1175/JCLI-D-21-0071.1  

   Jing, Renzhi; Lin, Ning; Emanuel, Kerry; Vecchi, Gabriel; Knutson, Thomas R. (August 2021, Journal of Climate)

   Abstract In this study, we investigate the response of tropical cyclones (TCs) to climate change by using the Princeton environment-dependent probabilistic tropical cyclone (PepC) model and a statistical-deterministic method to downscale TCs using environmental conditions obtained from the Geophysical Fluid Dynamics Laboratory (GFDL) High-resolution Forecast-oriented Low Ocean Resolution (HiFLOR) model, under the Representative Concentration Pathway 4.5 (RCP4.5) emissions scenario for the North Atlantic basin. The downscaled TCs for the historical climate (1986-2005) are compared with those in the mid- (2016-35) and late-twenty-first century (2081-2100). The downscaled TCs are also compared with TCs explicitly simulated in HiFLOR. We show that while significantly more storms are detected in HiFLOR towards the end of the twenty-first century, the statistical-deterministic model projects a moderate increase in TC frequency, and PepC projects almost no increase in TC frequency. The changes in storm frequency in all three datasets are not significant in the mid-twenty-first century. All three project that storms will become more intense and the fraction of major hurricanes and Category 5 storms will significantly increase in the future climates. However, HiFLOR projects the largest increase in intensity while PepC projects the least. The results indicate that HiFLOR’s TC projection is more sensitive to climate change effects and statistical models are less sensitive. Nevertheless, in all three datasets, storm intensification and frequency increase lead to relatively small changes in TC threat as measured by the return level of landfall intensity. 

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2. Response of Global Tropical Cyclone Activity to Increasing CO2: Results from Downscaling CMIP6 Models

   https://doi.org/10.1175/JCLI-D-20-0367.1  

   Emanuel, Kerry (January 2021, Journal of Climate)

   null (Ed.)

   Abstract Global models comprising the sixth-generation Coupled Climate Model Intercomparison Project (CMIP6) are downscaled using a very high-resolution but simplified coupled atmosphere–ocean tropical cyclone model, as a means of estimating the response of global tropical cyclone activity to increasing greenhouse gases. As with a previous downscaling of CMIP5 models, the results show an increase in both the frequency and severity of tropical cyclones, robust across the models downscaled, in response to increasing greenhouse gases. The increase is strongly weighted to the Northern Hemisphere, and especially noteworthy is a large increase in the higher latitudes of the North Atlantic. Changes are insignificant in the South Pacific across metrics. Although the largest increases in track density are far from land, substantial increases in global landfalling power dissipation are indicated. The incidence of rapid intensification increases rapidly with warming, as predicted by existing theory. Measures of robustness across downscaled climate models are presented, and comparisons to tropical cyclones explicitly simulated in climate models are discussed. 

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3. Increasing Flood Hazard Posed by Tropical Cyclone Rapid Intensification in a Changing Climate

   https://doi.org/10.1029/2023GL105624  

   Lockwood, Joseph W.; Lin, Ning; Gori, Avantika; Oppenheimer, Michael (February 2024, Geophysical Research Letters)

   Abstract Tropical cyclones (TCs) that undergo rapid intensification (RI) before landfall are notoriously difficult to predict and have caused tremendous damage to coastal regions in the United States. Using downscaled synthetic TCs and physics‐based models for storm tide and rain, we investigate the hazards posed by TCs that rapidly intensify before landfall under both historical and future mid‐emissions climate scenarios. In the downscaled synthetic data, the percentage of TCs experiencing RI is estimated to rise across a significant portion of the North Atlantic basin. Notably, future climate warming causes large increases in the probability of RI within 24 hr of landfall. Also, our analysis shows that RI events induce notably higher rainfall hazard levels than non‐RI events with equivalent TC intensities. As a result, RI events dominate increases in 100‐year rainfall and storm tide levels under climate change for most of the US coastline. 

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4. Tropical Cyclones in the NASA GEOS-5 Model and MERRA-2 Reanalysis

   Aarons, Zoe; Camargo, Suzana J.; Strong, Jeffrey D.; Murakami, Hiroyuki (January 2019, American Meteorological Society Annual Meeting, Abstract S251)

   Studies of projected changes in tropical cyclones under anthropogenic climate change, as well as their modulation by internal climate modes, make use of global climate models. To this end, tropical cyclones can be tracked in the output of higher resolution models. Using climate models to make future projections of tropical cyclones relies upon having a baseline of the characteristics of model storms under the current climate. This study focuses on two high-resolution datasets – the NASA GEOS-5 Model (Goddard Earth Observing System Model, Version 5) and the MERRA-2 Reanalysis (Modern-Era Retrospective analysis for Research and Applications, Version 2). Both of these datasets were created using exactly the same atmospheric model during the same period. However, while GEOS-5 is a free-running atmospheric model forced only with sea surface temperature, MERRA-2 is a reanalysis product, i.e. the model assimilates data from a large variety of data sources. Thus, by comparing tropical cyclones tracked in these datasets to each other and global best track datasets in the period 1980-1999, this project aims to evaluate 1) the sensitivity of this model to how it is forced and 2) how well the storms tracked in GEOS-5 and MERRA-2 replicate observed tropical cyclones’ characteristics. We used two different tracking schemes on both datasets and found no significant difference in the performance of the model and the reanalysis in simulating tropical cyclones. Standard diagnostics for tropical cyclones, such as the mean number, intensity distribution, as well as their interannual variability are very similar in the free-running model and the reanalysis. Both GEOS-5 and MERRA-2 show a bias towards weaker tropical cyclones than observed and GEOS-5 has storms that occur closer to the equator than in the observed record. Neither GEOS-5 nor MERRA-2 accurately reproduce tropical cyclone modulation by ENSO. Additionally, comparison of MERRA-2 to other reanalysis datasets shows that MERRA-2 on average generates fewer total but also more intense storms than the European Centre for Medium-Range Weather Forecasts Interim Reanalysis (ERA-Interim) and Japanese 55-Year Reanalysis (JRA-55). Further research must be performed to understand why this data assimilation is failing to provide a positive impact on the tropical cyclone simulation in this model. 

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5. 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. 

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