Synchronization between the zonal jet stream and temperature anomalies leads to the persistence of the January 2019 cold air outbreak in North America

The recent rapid warming of the Arctic atmosphere and ocean and related sea ice decline have been associated with increasing occurrence of extreme weather events in the Arctic. Applying ERA-Interim reanalysis, we identify 100 days with largest positive and negative anomalies (compared to local climatology) in 2-m air temperature (T2m) in the Northern Hemisphere in winter during 2005-2019, and address various physical mechanisms contributing to these events. The mechanisms responsible for warm extremes in the Arctic are often associated with a meandering Polar front jet stream, favouring cases of large transports of heat and moisture from mid-latitudes to the Arctic. In addition, subsidence heating often contributes to warm extremes in the Arctic, allowing them to occur also under high-pressure conditions. The coldest T2m anomalies north of 30oN mostly occur in regions that are also climatologically cold, i.e., cannot be strongly affected by cold-air advection. This suggests a dominating role local surface energy budget and boundary-layer processes.Extreme weather events often interact with anomalies in sea ice concentration. Cases of strong winds transporting warm, moist air masses to the Arctic provide both dynamic and thermodynamic forcing for large sea ice anomalies, and during winter the openings in sea ice field contribute to air temperature extremes via large heat fluxes from the ocean to atmosphere.Coldest winter extremes in mid-latitudes are typically associated with meandering jet stream and high-pressure blockings, but show differences between Central Europe, North America and northern China. In Central Europe the coldest events are typically associated with cold-air advection from the East or Northeast, whereas during the coldest events in North American East Coast the cold air is transported from the North. In northern China, the coldest events often occur under high-pressure conditions with weak winds. Accordingly, the role of cold-air advection is much smaller than in the case of the coldest events in North America.

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The Synchronization between the Zonal Jet Stream and Temperature Anomalies Leads to an Extremely Freezing North America in January 2019

Geophysical Research Letters ◽

10.1029/2020gl089689 ◽

2020 ◽

Vol 47 (19) ◽

Author(s):

Fen Xu ◽

X. San Liang

Keyword(s):

North America ◽

Jet Stream ◽

Temperature Anomalies

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Cold air outbreak over the Kuroshio extension region

OCEANS 2009 ◽

10.23919/oceans.2009.5422391 ◽

2009 ◽

Author(s):

T. G. Jensen ◽

T. Campbell ◽

T. A. Smith ◽

R. J. Small ◽

R. Allard

Keyword(s):

Kuroshio Extension ◽

Cold Air ◽

Cold Air Outbreak ◽

The Kuroshio ◽

Kuroshio Extension Region

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A Comparison of North American Surface Temperature and Temperature Extreme Anomalies in Association with Various Atmospheric Teleconnection Patterns

Atmosphere ◽

10.3390/atmos10040172 ◽

2019 ◽

Vol 10 (4) ◽

pp. 172 ◽

Cited By ~ 5

Author(s):

Bin Yu ◽

Hai Lin ◽

Nicholas Soulard

Keyword(s):

North America ◽

Surface Temperature ◽

North Atlantic ◽

North American ◽

North Pacific ◽

Temperature Anomaly ◽

Temperature Extreme ◽

Associated Anomalies ◽

Atmospheric Teleconnection ◽

Temperature Anomalies

The atmospheric teleconnection pattern reflects large-scale variations in the atmospheric wave and jet stream, and has pronounced impacts on climate mean and extremes over various regions. This study compares those patterns that have significant circulation anomalies over the North Pacific–North American–North Atlantic sector, which directly influence surface temperature and temperature extremes over North America. We analyze the pattern associated anomalies of surface temperature and warm and cold extremes over North America, during the northern winter and summer seasons. In particular, we assess the robustness of the regional temperature and temperature extreme anomaly patterns by evaluating the field significance of these anomalies over North America, and quantify the percentages of North American temperature and temperature extreme variances explained by these patterns. The surface temperature anomalies in association with the Pacific–North American pattern (PNA), Tropical–Northern Hemisphere pattern (TNH), North Pacific pattern (NP), North Atlantic Oscillation (NAO), Arctic Oscillation (AO), Western Pacific pattern (WP), circumglobal teleconnection (CGT), and Asian–Bering–North American (ABNA) patterns are similar to those reported in previous studies based on various datasets, indicating the robustness of the results. During winter, the temperature anomaly patterns considered are field significant at the 5% level over North America, except the WP-related one. These pattern associated anomalies explained about 5–15% of the total interannual temperature variance over North America, with relatively high percentages for the ABNA and PNA patterns, and low for the WP pattern. The pattern associated warm and cold extreme anomalies resemble the corresponding surface mean temperature anomaly patterns, with differences mainly in magnitude of the anomalies. Most of the anomalous extreme patterns are field significant at the 5% level, except the WP-related patterns. These extreme anomalies explain about 5–20% of the total interannual variance over North America. During summer, the pattern-related circulation and surface temperature anomalies are weaker than those in winter. Nevertheless, all of the pattern associated temperature anomalies are of field significance at the 5% level over North America, except the PNA-related one, and explain about 5–10% of the interannual variance. In addition, the temperature extreme anomalies, in association with the circulation patterns, are comparable in summer and winter. Over North America, the NP-, WP-, ABNA-, and CGT-associated anomalies of warm extremes are field significant at the 5% level and explain about 5–15% of the interannual variance. Most of the pattern associated cold extreme anomalies are field significant at the 5% level, except the PNA and NAO related anomalies, and also explain about 5–15% of the interannual variance over North America.

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Distorted Pacific–North American teleconnection at the Last Glacial Maximum

Climate of the Past ◽

10.5194/cp-16-199-2020 ◽

2020 ◽

Vol 16 (1) ◽

pp. 199-209 ◽

Cited By ~ 4

Author(s):

Yongyun Hu ◽

Yan Xia ◽

Zhengyu Liu ◽

Yuchen Wang ◽

Zhengyao Lu ◽

...

Keyword(s):

North America ◽

Last Glacial Maximum ◽

North American ◽

Tropical Pacific ◽

Glacial Maximum ◽

Jet Stream ◽

Last Glacial ◽

The Last Glacial Maximum ◽

The Tropical Pacific ◽

The Last Glacial

Abstract. The Pacific–North American (PNA) teleconnection is one of the most important climate modes in the present climate condition, and it enables climate variations in the tropical Pacific to exert a significant influence on North America. Here, we show climate simulations in which the PNA teleconnection was largely distorted or broken at the Last Glacial Maximum (LGM). The distorted PNA is caused by a split in the westerly jet stream, which is ultimately forced by the large, thick Laurentide ice sheet that was present at the LGM. Changes in the jet stream greatly alter the extratropical waveguide, distorting wave propagation from the North Pacific to North America. The distorted PNA suggests that climate variability in the tropical Pacific, notably El Niño–Southern Oscillation (ENSO), would have little direct impact on North American climate at the LGM.

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A case study of snowstorm gusts and blowing/drifting snow

Annals of Glaciology ◽

10.3189/s026030550001140x ◽

1993 ◽

Vol 18 ◽

pp. 142-148 ◽

Cited By ~ 1

Author(s):

Masayuki Maki ◽

Sento Nakai ◽

Tsuruhei Yagi ◽

Hideomi Nakamura

Keyword(s):

Doppler Radar ◽

Gravity Current ◽

Ground Surface ◽

Leading Edge ◽

Radiosonde Data ◽

The Sea Of Japan ◽

Cold Air ◽

Drifting Snow ◽

Cold Air Outbreak ◽

Strong Winds

The mechanisms of strong winds associated with snow clouds, and the relationship between strong winds and blowing/drifting snow, were investigated. A snowstorm occurred with a typical L-mode snow band which was generated and organized longitudinally during a continental cold-air outbreak over the Sea of Japan. Doppler radar observations revealed that the snow band consisted of small echo cells arranged along the direction of the snow band. When one of the echo cells passed, blowing/drifting snow was generated and intensified by a snow cloud-induced gust, and the horizontal visibility near the ground surface was significantly decreased. Doppler radar and radiosonde data showed that the gust was due to the cold air outflow (CAO) from the snow clouds. The leading edge of the CAO was about 9 km ahead of the center of the snow cloud and the depth of the CAO was about 600 m near the forward flank of the snow cloud. The CAO was caused by a downdraft at the center of the snow cloud, which was initiated at a height of about 1.3 km and with a velocity in excess of 1 ms−1. The observed CAO speed was explained by the theory of the gravity current.

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