Modeling high-impact weather and climate: lessons from a tropical cyclone perspective

Done, James M.; Holland, Greg J.; Bruyère, Cindy L.; Leung, L. Ruby; Suzuki-Parker, Asuka

doi:10.1007/s10584-013-0954-6

Cited by 117 publications

(112 citation statements)

References 49 publications

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“…We further compare the observed changes to recent climate simulations with the dynamical downscaling results of Bender et al (2010), Done et al (2012), and Wu and Zhao (2012).…”

Section: Datamentioning

confidence: 97%

“…Bender et al (2010) found that for each°C of global warming the proportion of Cat 4-5 hurricanes increased by *11 % and the proportion of Cat 1-2 hurricanes decreased by *7 %. Done et al (2012) applied Weibull and Generalized Pareto distributions to assess the expected changes in future North Atlantic hurricane extremes based on changes to the mean and variance of the truncated distribution predicted by the NCAR Nested Regional Climate Model (Done et al 2012). Both approaches showed that relatively modest increases in the mean (3 %) and standard deviation of (7 %) produced an increase in the proportion of Cat 4-5 hurricanes of *15 % per°C of global warming.…”

Section: Comparison With Model Simulationsmentioning

confidence: 99%

“…It is often assumed that this means negligible change in hurricane extremes, but this can easily be shown to be incorrect by fitting an extreme distribution to the tropical cyclone PDF and examining the changes in extremes resulting from small bulk changes. For example, by fitting a Weibull distribution to the current tropical cyclone PDF [see Done et al (2012) for discussion on the method] it can readily be shown that a change of 2-3 m s -1 in both the mean and standard deviation-similar to the resolution of the IBTrACS-produces a *20 % increase in the proportion (equivalent to doubling) of Cat 4-5 hurricanes. Such a sensitivity of the extremes to relatively small changes in the mean and standard deviation is well known and has been emphasized by the IPCC (2012, their Fig.…”

Section: Comparison With Extreme Value Analysismentioning

confidence: 99%

“…Obviously this linear increase cannot go on indefinitely as the proportion of Cat 4-5 hurricanes cannot exceed one. Table 2 compares the different values and base periods for the North Atlantic observations with the downscaling by Bender et al (2010) and Done et al (2012). No adjustment downward was made to the observed Atlantic trend due to analysis issues since North Atlantic intensity archives are reasonably accurate over the period (Kossin et al 2007).…”

Section: Where Is the Limit?mentioning

confidence: 99%

“…The increases are substantial, approaching a doubling in frequency of Cat 4 and 5 hurricanes [based on the Saffir-Simpson classification, Simpson and Rielh (1981)] for each°C in global warming (Bender et al 2010;IPCC 2012;Done et al 2012). IPCC (2007) also concluded that the current 'warming of the climate system is unequivocal'.…”

Section: Introductionmentioning

confidence: 99%

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Recent intense hurricane response to global climate change

2013

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An Anthropogenic Climate Change Index (ACCI) is developed and used to investigate the potential global warming contribution to current tropical cyclone activity. The ACCI is defined as the difference between the means of ensembles of climate simulations with and without anthropogenic gases and aerosols. This index indicates that the bulk of the current anthropogenic warming has occurred in the past four decades, which enables improved confidence in assessing hurricane changes as it removes many of the data issues from previous eras. We find no anthropogenic signal in annual global tropical cyclone or hurricane frequencies. But a strong signal is found in proportions of both weaker and stronger hurricanes: the proportion of Category 4 and 5 hurricanes has increased at a rate of *25-30 % per°C of global warming after accounting for analysis and observing system changes. This has been balanced by a similar decrease in Category 1 and 2 hurricane proportions, leading to development of a distinctly bimodal intensity distribution, with the secondary maximum at Category 4 hurricanes. This global signal is reproduced in all ocean basins. The observed increase in Category 4-5 hurricanes may not continue at the same rate with future global warming. The analysis suggests that following an initial climate increase in intense hurricane proportions a saturation level will be reached beyond which any further global warming will have little effect.

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“…We further compare the observed changes to recent climate simulations with the dynamical downscaling results of Bender et al (2010), Done et al (2012), and Wu and Zhao (2012).…”

Section: Datamentioning

confidence: 97%

Section: Comparison With Model Simulationsmentioning

confidence: 99%

Section: Comparison With Extreme Value Analysismentioning

confidence: 99%

Section: Where Is the Limit?mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Recent intense hurricane response to global climate change

2013

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Long‐term variations of North Atlantic tropical cyclone activity downscaled from a coupled model simulation of the last millennium

et al. 2013

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[1] The observed historical record of North Atlantic tropical cyclones (TCs) is relatively short and is subject to potential biases owing to a lack of observation platforms such as aircraft reconnaissance and satellite imagery in earlier decades. Therefore, studies of long-term variability in TC activity are hindered by the limitations and uncertainty within the historical data. An alternative approach is to study long-term Atlantic TC variability within the framework of a coupled ocean-atmosphere climate model simulation. We have taken such an approach using a simulation of the National Center for Atmospheric Research Climate System Model 1.4 forced with estimated natural and anthropogenic forcing over the past millennium. Atmospheric variables from the long-term model simulation are used to drive a recently developed downscaling relationship that simulates TC genesis and tracking over the course of the 1150 year model simulation. This downscaling process generates a long-term synthetic TC track data set, free of observational biases, though subject to limitations in the model climatology. The synthetic TC data are used to perform an analysis of long-term variability in Atlantic TCs, specifically focusing on TC landfalls, within the context of the coupled model simulation. Ultimately, analysis of various TC time series reveals that counts of landfalling TCs and even landfalling hurricanes track relatively well with the total basin-wide TC activity on multidecadal and longer timescales.

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Projections of future summertime ozone over the U.S.

et al. 2014

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We use a regional coupled chemistry-transport model to assess changes in surface ozone over the summertime U.S. between present and a 2050 future time period at high spatial resolution under the A2 climate and Representative Concentration Pathway (RCP) 8.5 anthropogenic precursor emission scenarios. Predicted changes in regional climate and globally enhanced ozone are estimated to increase surface ozone over most of the U.S.; the 95th percentile for daily 8 h maximum surface ozone increases from 79 ppb to 87 ppb. The analysis suggests that changes in meteorological drivers likely will add to increasing ozone, but the simulations do not allow separating meteorological feedbacks from that due to enhanced global ozone. Stringent emission controls can counteract these feedbacks; if implemented as in RCP8.5, the 95th percentile for surface ozone is reduced to 55 ppb. A comparison of regional to global model projections shows that the global model is biased high in surface ozone compared to the regional model and compared to observations. On average, both the global and the regional model predict similar future changes but reveal pronounced differences in urban and rural regimes that cannot be resolved at the coarse resolution of the considered global model. This study confirms the key role of emission control strategies in future air quality projections and demonstrates the need for considering degradation of air quality with future climate change in policy making. It also illustrates the need for high-resolution modeling when the objective is to address regional and local air quality or establish links to human health and society.

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Modeling high-impact weather and climate: lessons from a tropical cyclone perspective

Cited by 117 publications

References 49 publications

Recent intense hurricane response to global climate change

Recent intense hurricane response to global climate change

Long‐term variations of North Atlantic tropical cyclone activity downscaled from a coupled model simulation of the last millennium

Projections of future summertime ozone over the U.S.

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