Showing total 4 results

1. Role of atmospheric rivers in shaping long term Arctic moisture variability.

Author

Wang, Zhibiao, Ding, Qinghua, Wu, Renguang, Ballinger, Thomas J., Guan, Bin, Bozkurt, Deniz, Nash, Deanna, Baxter, Ian, Topál, Dániel, Li, Zhe, Huang, Gang, Chen, Wen, Chen, Shangfeng, Cao, Xi, and Chen, Zhang

Subjects

ATMOSPHERIC rivers, HUMIDITY, MOISTURE, GLOBAL warming, WATER vapor transport

Abstract

Atmospheric rivers (ARs) reaching high-latitudes in summer contribute to the majority of climatological poleward water vapor transport into the Arctic. This transport has exhibited long term changes over the past decades, which cannot be entirely explained by anthropogenic forcing according to ensemble model responses. Here, through observational analyses and model experiments in which winds are adjusted to match observations, we demonstrate that low-frequency, large-scale circulation changes in the Arctic play a decisive role in regulating AR activity and thus inducing the recent upsurge of this activity in the region. It is estimated that the trend in summertime AR activity may contribute to 36% of the increasing trend of atmospheric summer moisture over the entire Arctic since 1979 and account for over half of the humidity trends in certain areas experiencing significant recent warming, such as western Greenland, northern Europe, and eastern Siberia. This indicates that AR activity, mostly driven by strong synoptic weather systems often regarded as stochastic, may serve as a vital mechanism in regulating long term moisture variability in the Arctic. More atmospheric rivers bringing moisture into the Arctic have been observed in summers of recent decades and have been linked to global warming and Arctic Amplification. In contrast, this study finds that natural forcing relative to large-scale circulation changes is behind this shift. [ABSTRACT FROM AUTHOR]

Published

2024

2. Evolutionary history of the Arctic flora.

Author

Zhang, Jun, Li, Xiao-Qian, Peng, Huan-Wen, Hai, Lisi, Erst, Andrey S., Jabbour, Florian, Ortiz, Rosa del C., Xia, Fu-Cai, Soltis, Pamela S., Soltis, Douglas E., and Wang, Wei

Subjects

BOTANY, ARCTIC climate, CLIMATE change, GLOBAL warming, LANDSCAPE changes

Abstract

The Arctic tundra is a relatively young and new type of biome and is especially sensitive to the impacts of global warming. However, little is known about how the Arctic flora was shaped over time. Here we investigate the origin and evolutionary dynamics of the Arctic flora by sampling 32 angiosperm clades that together encompass 3626 species. We show that dispersal into the Arctic and in situ diversification within the Arctic have similar trends through time, initiating at approximately 10–9 Ma, increasing sharply around 2.6 Ma, and peaking around 1.0–0.7 Ma. Additionally, we discover the existence of a long-term dispersal corridor between the Arctic and western North America. Our results suggest that the initiation and diversification of the Arctic flora might have been jointly driven by progressive landscape and climate changes and sea-level fluctuations since the early Late Miocene. These findings have important conservation implications given rapidly changing climate conditions in the Arctic. The Arctic tundra is a relatively young biome. Here, the authors sample 32 angiosperm clades encompassing 3600+ species and find that both long-term dispersal and in situ speciation may have contributed to Arctic flora assembly, in association with landscape, climate and sea-level changes since the early Late Miocene. [ABSTRACT FROM AUTHOR]

Published

2023

3. Thawing permafrost poses environmental threat to thousands of sites with legacy industrial contamination.

Author

Langer, Moritz, von Deimling, Thomas Schneider, Westermann, Sebastian, Rolph, Rebecca, Rutte, Ralph, Antonova, Sofia, Rachold, Volker, Schultz, Michael, Oehme, Alexander, and Grosse, Guido

Subjects

INDUSTRIAL contamination, INDUSTRIAL sites, PERMAFROST, HAZARDOUS waste sites, GLOBAL warming

Abstract

Industrial contaminants accumulated in Arctic permafrost regions have been largely neglected in existing climate impact analyses. Here we identify about 4500 industrial sites where potentially hazardous substances are actively handled or stored in the permafrost-dominated regions of the Arctic. Furthermore, we estimate that between 13,000 and 20,000 contaminated sites are related to these industrial sites. Ongoing climate warming will increase the risk of contamination and mobilization of toxic substances since about 1100 industrial sites and 3500 to 5200 contaminated sites located in regions of stable permafrost will start to thaw before the end of this century. This poses a serious environmental threat, which is exacerbated by climate change in the near future. To avoid future environmental hazards, reliable long-term planning strategies for industrial and contaminated sites are needed that take into account the impacts of cimate change. Thousands of industrial sites were found to be correlated with contaminated sites in the Arctic. Between 13,000 and 20,000 contaminated sites are likely to exist in the permafrost region, 26% of which will be affected by permafrost thaw before 2100. [ABSTRACT FROM AUTHOR]

Published

2023

4. New climate models reveal faster and larger increases in Arctic precipitation than previously projected.

Author

McCrystall, Michelle R., Stroeve, Julienne, Serreze, Mark, Forbes, Bruce C., and Screen, James A.

Subjects

ATMOSPHERIC models, HYDROLOGIC cycle, GLOBAL warming, SEA ice, TWENTY-first century

Abstract

As the Arctic continues to warm faster than the rest of the planet, evidence mounts that the region is experiencing unprecedented environmental change. The hydrological cycle is projected to intensify throughout the twenty-first century, with increased evaporation from expanding open water areas and more precipitation. The latest projections from the sixth phase of the Coupled Model Intercomparison Project (CMIP6) point to more rapid Arctic warming and sea-ice loss by the year 2100 than in previous projections, and consequently, larger and faster changes in the hydrological cycle. Arctic precipitation (rainfall) increases more rapidly in CMIP6 than in CMIP5 due to greater global warming and poleward moisture transport, greater Arctic amplification and sea-ice loss and increased sensitivity of precipitation to Arctic warming. The transition from a snow- to rain-dominated Arctic in the summer and autumn is projected to occur decades earlier and at a lower level of global warming, potentially under 1.5 °C, with profound climatic, ecosystem and socio-economic impacts. The Arctic warms faster than other areas of the planet, which also influences precipitation. Here, the authors show that the latest CMIP6 model ensemble shows a faster Arctic warming and sea-ice loss, causing an earlier transition from a snow- to a rain-dominated Arctic than previously thought. [ABSTRACT FROM AUTHOR]

Published

2021