Diagnosing Non‐Gaussian Temperature Distribution Tails Using Back‐Trajectory Analysis

Catalano, A. J.; Loikith, Paul C.; Neelin, J. David

doi:10.1029/2020jd033726

Cited by 4 publications

(4 citation statements)

References 55 publications

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“…The result is more negatively skewed temperature (Figure S12 in Supporting Information ; from −0.27 to −0.42), reducing heatwave days from 1.93 historically to 1.59 in the future. In addition to the effect of soil moisture‐atmosphere interactions, dynamical impact such as the effect of storm tracks and meridional advection may play an important role in shaping the spatial structure of temperature skewness (Catalano et al., 2021; Tamarin‐Brodsky et al., 2019), which deserves further investigation.…”

Section: Resultsmentioning

confidence: 99%

More Frequent and Persistent Heatwaves Due To Increased Temperature Skewness Projected by a High‐Resolution Earth System Model

Gao,

Wu,

Guo

et al. 2023

Geophysical Research Letters

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Heatwaves are strongly associated with temperature distributions, but the mechanisms by which distributions are influenced by climate change remains unclear. Comparing simulations from a high‐spatial resolution Community Earth System Model (CESM‐HR) with those from low‐resolution models, we identify substantial improvements by CESM‐HR in reproducing observed Northern Hemisphere summer temperature skewness, as well as the frequency, intensity, persistence, and total heatwave days. Temperature skewness is strongly linked to land‐atmosphere interactions and atmospheric circulation. Under global warming projections, some regions exhibit enhanced temperature skewness, along with more frequent and persistent heatwaves of greater intensity. We find that in energy‐limited regimes, such as India, negative skewness in latent heat flux facilitates large positive skewness in sensible heat flux, which modulates near‐surface air temperatures. Skewness differences of latent and sensible heat fluxes are amplified under global warming, increasing the temperature skewness. We find that this contrasting flux mechanism is active in several heatwave‐prone regions.

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Section: Resultsmentioning

confidence: 99%

More Frequent and Persistent Heatwaves Due To Increased Temperature Skewness Projected by a High‐Resolution Earth System Model

Gao,

Wu,

Guo

et al. 2023

Geophysical Research Letters

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“…A very high daily mean T W can also be suggestive of high nighttime T W , prolonging exposure to heat stress (Kravchenko et al., 2013). It is possible that in some cases, the prevailing meteorology that causes the short tails may also prevent T W from becoming too high, such as is seen with temperature distributions (Catalano et al., 2021).…”

Section: Discussionmentioning

confidence: 99%

“…Another complicating factor in the increase of T W extremes is the shape of the T W probability distribution. The non‐Gaussian nature of temperature climatology is well‐established (Catalano et al., 2021; Garfinkel & Harnik, 2017; Linz et al., 2018; Perron & Sura, 2013; Simolo et al., 2010, 2011; B. Zhang et al., 2022), and some physical explanations have been offered, generally related to underlying horizontal temperature gradients (Catalano et al., 2021; Garfinkel & Harnik, 2017; Linz et al., 2018; Perron & Sura, 2013), but non‐Gaussianity in T W distributions has not been explored to our knowledge. Tail shape relative to a Gaussian strongly influences the rate of changes in exceedances over a fixed extreme temperature threshold, and a shorter‐than‐Gaussian warm tail can lead to a greater increase in extreme warm exceedances under global warming than if the tail were Gaussian or longer (Loikith et al., 2018; Loikith and Neelin, 2015, 2019; Ruff & Neelin, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Another complicating factor in the increase of T W extremes is the shape of the T W probability distribution. The non-Gaussian nature of temperature climatology is well-established (Catalano et al, 2021;Garfinkel & Harnik, 2017;Linz et al, 2018;Perron & Sura, 2013;Simolo et al, 2010Simolo et al, , 2011B. Zhang et al, 2022), and some physical explanations have been offered, generally related to underlying horizontal temperature gradients (Catalano et al, 2021;Garfinkel & Harnik, 2017;Linz et al, 2018;Perron & Sura, 2013), but non-Gaussianity in T W distributions has not been explored to our knowledge.…”

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confidence: 99%

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Short Warm Distribution Tails Accelerate the Increase of Humid‐Heat Extremes Under Global Warming

Bekris

Loikith

Neelin

2023

Geophysical Research Letters

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Humid‐heat extremes threaten human health and are increasing in frequency with global warming, so elucidating factors affecting their rate of change is critical. We investigate the role of wet‐bulb temperature (TW) frequency distribution tail shape on the rate of increase in extreme TW threshold exceedances under 2°C global warming. Results indicate that non‐Gaussian TW distribution tails are common worldwide across extensive, spatially coherent regions. More rapid increases in the number of days exceeding the historical 95th percentile are projected in locations with shorter‐than‐Gaussian warm side tails. Asymmetry in the specific humidity distribution, one component of TW, is more closely correlated with TW tail shape than temperature, suggesting that humidity climatology strongly influences the rate of future changes in TW extremes. Short non‐Gaussian TW warm tails have notable implications for dangerous humid‐heat in regions where current‐climate TW extremes approach human safety limits.

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Projected Changes in Atmospheric Ridges over the Pacific–North American Region Using CMIP6 Models

2022

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Projected changes in atmospheric ridges and associated temperature and precipitation anomalies are assessed for the end of the twenty-first century in a suite of 27 models contributing to phase 6 of the Coupled Model Intercomparison Project (CMIP6) under a high-end emissions scenario over the Pacific–North American region. Ridges are defined as spatially coherent regions of positive zonal anomalies in 500-hPa geopotential height. The frequency of ridge days in the historical period varies by geography and season; however, ridge days are broadly more common over the region in winter and least common in summer. The CMIP6 models are credible in reproducing key features of reanalysis-derived ridge climatology. The CMIP6 models also reproduce historical temperature and precipitation anomalies associated with ridges. These associations include positive temperature anomalies over and to the west/northwest of the ridge peak and negative precipitation anomalies southeast of the ridge peak. Future projections show a general decrease in ridge days across most of the region in fall through spring, with considerable model agreement. Projections for summer are different, with robust projections of increases in the number of ridge days across parts of the interior western United States and Canada. The CMIP6 models project modest decreases in the probability of stronger ridges and modest increases in the probability of weaker ridges in fall and winter. Future ridges show similar temperature and precipitation anomaly associations as in the historical climate period, when future anomalies are computed relative to future climatology. Significance Statement Atmospheric ridges over the Pacific–North American region are a type of atmospheric circulation pattern associated with important weather and climate impacts. These impacts include heatwaves and drought. This study uses climate models to understand how ridges and their impacts may change under future climate warming. The results suggest that ridge days will be less common across parts of the domain in fall, winter, and spring. In summer, an increase in ridge days is projected in a region centered on Montana. Results suggest that temperature and precipitation patterns associated with ridges will change at a similar rate to the overall mean climate. This work provides evidence that continued climate warming will alter atmospheric circulation over the Pacific–North American region in complex ways.

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Diagnosing Non‐Gaussian Temperature Distribution Tails Using Back‐Trajectory Analysis

Cited by 4 publications

References 55 publications

More Frequent and Persistent Heatwaves Due To Increased Temperature Skewness Projected by a High‐Resolution Earth System Model

More Frequent and Persistent Heatwaves Due To Increased Temperature Skewness Projected by a High‐Resolution Earth System Model

Short Warm Distribution Tails Accelerate the Increase of Humid‐Heat Extremes Under Global Warming

Projected Changes in Atmospheric Ridges over the Pacific–North American Region Using CMIP6 Models

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