Your search keyword '"Horton, Radley M."' showing total 5 results

1. Arctic sea-ice loss is projected to lead to more frequent strong El Niño events.

Author

Liu, Jiping, Song, Mirong, Zhu, Zhu, Horton, Radley M., Hu, Yongyun, and Xie, Shang-Ping

Subjects

SEA ice, CLIMATE extremes, MODES of variability (Climatology), CLIMATE change, GREENHOUSE gases, TWENTY-first century

Abstract

Arctic sea ice has decreased substantially and is projected to reach a seasonally ice-free state in the coming decades. Little is known about whether dwindling Arctic sea ice is capable of influencing the occurrence of strong El Niño, a prominent mode of climate variability with global impacts. Based on time slice coupled model experiments, here we show that no significant change in the occurrence of strong El Niño is found in response to moderate Arctic sea-ice loss that is consistent with satellite observations to date. However, as the ice loss continues and the Arctic becomes seasonally ice-free, the frequency of strong El Niño events increases by more than one third, as defined by gradient-based indices that remove mean tropical Pacific warming induced by the seasonally ice-free Arctic. By comparing our time slice experiments with greenhouse warming experiments, we conclude that at least 37–48% of the increase of strong El Niño near the end of the 21st century is associated specifically with Arctic sea-ice loss. Further separation of Arctic sea-ice loss and greenhouse gas forcing only experiments implies that the seasonally ice-free Arctic might play a key role in driving significantly more frequent strong El Niño events. With an ice-free Arctic, strong El Niño frequency increases 1/3 +. Almost half the increase by 2100 links to Arctic ice loss, not other greenhouse forcing. The Arctic's influence on ENSO may represent a novel driver of changing climate extremes globally. [ABSTRACT FROM AUTHOR]

Published

2022

2. Recent Increases in Exposure to Extreme Humid‐Heat Events Disproportionately Affect Populated Regions.

Author

Rogers, Cassandra D. W., Ting, Mingfang, Li, Cuihua, Kornhuber, Kai, Coffel, Ethan D., Horton, Radley M., Raymond, Colin, and Singh, Deepti

Subjects

CLIMATE extremes, HIGH temperatures

Abstract

Extreme heat research has largely focused on dry‐heat, while humid‐heat that poses a substantial threat to human‐health remains relatively understudied. Using hourly high‐resolution ERA5 reanalysis and HadISD station data, we provide the first spatially comprehensive, global‐scale characterization of the magnitude, seasonal timing, and frequency of dry‐ and wet‐bulb temperature extremes and their trends. While the peak dry‐ and humid‐heat extreme occurrences often coincide, their timing differs in climatologically wet regions. Since 1979, dry‐ and humid‐heat extremes have become more frequent over most land regions, with the greatest increases in the tropics and Arctic. Humid‐heat extremes have increased disproportionately over populated regions (∼5.0 days per‐person per‐decade) relative to global land‐areas (∼3.6 days per‐unit‐land‐area per‐decade) and population exposure to humid‐heat has increased at a faster rate than to dry‐heat. Our study highlights the need for a multivariate approach to understand and mitigate future harm from heat stress in a warming world. Plain Language Summary: Combined high temperature and humidity can be more dangerous to humans and wildlife relative to high temperature alone. There are known physiological limits to humid‐heat and adverse impacts on human‐health and performance can be felt well below those limits. Thus, it is important we understand their climatological characteristics and recent changes. Prior research on heat extremes has largely focused on dry‐heat. Using two high‐spatial resolution datasets, we provide a global‐scale characterization of the magnitude, seasonal timing, and frequency of dry‐ and humid‐heat extremes and their historical trends. While dry‐ and humid‐heat extremes occur at the same time of the year in most regions, their timing differs by multiple months in tropical regions with high rainfall. Over the past four decades, dry‐ and humid‐heat extremes have become more frequent over most land regions, with the greatest increases in the tropics and Arctic. Since 1979, each person, on average, has experienced an increase of approximately five additional extreme humid‐heat days per‐decade. These increases are concentrated over densely populated regions in the tropics and sub‐tropics, where humid‐heat levels are already high. Our results emphasize the increasing risk from dangerous heat stress, particularly in vulnerable regions of the world. Key Points: Global patterns and trends in magnitude, timing, and frequency of dry and humid‐heat extremes in ERA5 compare well with HadISD station dataLargest increases in frequency, intensity, and months of occurrence of dry‐ and humid‐heat extremes in tropical and Arctic regionsStronger trends in population exposure to extreme humid‐heat relative to dry‐heat and greater amplification during recent El Niños [ABSTRACT FROM AUTHOR]

Published

2021

3. Impact of declining Arctic sea ice on winter snowfall.

Author

Jiping Liu, Curry, Judith A., Huijun Wang, Mirong Song, and Horton, Radley M.

Subjects

SNOW, ATMOSPHERIC circulation, ARCTIC oscillation, CLIMATOLOGY

Abstract

While the Arctic region has been warming strongly in recent decades, anomalously large snowfall in recent winters has affected large parts of North America, Europe, and east Asia. Here we demonstrate that the decrease in autumn Arctic sea ice area is linked to changes in the winter Northern Hemisphere atmospheric circulation that have some resemblance to the negative phase of the winter Arctic oscillation. However, the atmospheric circulation change linked to the reduction of sea ice shows much broader meridional meanders in midlatitudes and clearly different interannual variability than the classical Arctic oscillation. This circulation change results in more frequent episodes of blocking patterns that lead to increased cold surges over large parts of northern continents. Moreover, the increase in atmospheric water vapor content in the Arctic region during late autumn and winter driven locally by the reduction of sea ice provides enhanced moisture sources, supporting increased heavy snowfall in Europe during early winter and the northeastern and midwestern United States during winter. We conclude that the recent decline of Arctic sea ice has played a critical role in recent cold and snowy winters. [ABSTRACT FROM AUTHOR]

Published

2012

4. Reducing spread in climate model projections of a September ice-free Arctic.

Author

Liu J, Song M, Horton RM, and Hu Y

Subjects

Arctic Regions, Global Warming, Models, Theoretical, Seasons

Abstract

This paper addresses the specter of a September ice-free Arctic in the 21st century using newly available simulations from the Coupled Model Intercomparison Project Phase 5 (CMIP5). We find that large spread in the projected timing of the September ice-free Arctic in 30 CMIP5 models is associated at least as much with different atmospheric model components as with initial conditions. Here we reduce the spread in the timing of an ice-free state using two different approaches for the 30 CMIP5 models: (i) model selection based on the ability to reproduce the observed sea ice climatology and variability since 1979 and (ii) constrained estimation based on the strong and persistent relationship between present and future sea ice conditions. Results from the two approaches show good agreement. Under a high-emission scenario both approaches project that September ice extent will drop to ∼1.7 million km(2) in the mid 2040s and reach the ice-free state (defined as 1 million km(2)) in 2054-2058. Under a medium-mitigation scenario, both approaches project a decrease to ∼1.7 million km(2) in the early 2060s, followed by a leveling off in the ice extent.

Published

2013

5. Impact of declining Arctic sea ice on winter snowfall.

Author

Liu J, Curry JA, Wang H, Song M, and Horton RM

Subjects

Air, Arctic Regions, Linear Models, Pressure, Temperature, Time Factors, Ice Cover, Seasons, Snow

Abstract

While the Arctic region has been warming strongly in recent decades, anomalously large snowfall in recent winters has affected large parts of North America, Europe, and east Asia. Here we demonstrate that the decrease in autumn Arctic sea ice area is linked to changes in the winter Northern Hemisphere atmospheric circulation that have some resemblance to the negative phase of the winter Arctic oscillation. However, the atmospheric circulation change linked to the reduction of sea ice shows much broader meridional meanders in midlatitudes and clearly different interannual variability than the classical Arctic oscillation. This circulation change results in more frequent episodes of blocking patterns that lead to increased cold surges over large parts of northern continents. Moreover, the increase in atmospheric water vapor content in the Arctic region during late autumn and winter driven locally by the reduction of sea ice provides enhanced moisture sources, supporting increased heavy snowfall in Europe during early winter and the northeastern and midwestern United States during winter. We conclude that the recent decline of Arctic sea ice has played a critical role in recent cold and snowy winters.

Published

2012