Mark C. Serreze’s research while affiliated with University of Colorado and other places
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Arctic observations in 2023 provided clear evidence of rapid and pronounced climate and environmental change, shaped by past and ongoing human activities that release greenhouse gases into the atmosphere and push the broader Earth system into uncharted territory. This chapter provides a snapshot of 2023 and summarizes decades-long trends observed across the Arctic, including warming surface air and sea-surface temperatures, decreasing snow cover, diminishing sea ice, thawing permafrost, and continued mass loss from the Greenland Ice Sheet and Arctic glaciers. These changes are driving a transition to a wetter, greener, and less frozen Arctic, with serious implications for Arctic peoples and ecosystems, as well as for low- and midlatitudes.
Arctic communities are experienced with severe weather, but impacts can still be serious, particularly when the intensity or persistence of hazardous conditions is extreme. Such was the case for the community of Clyde River (Kangiqtugaapik), Nunavut, Canada, which experienced 33 blizzard days during winter 2021/22—likely the most at Clyde River since at least 1978/79. Blizzard conditions resulted from unusually frequent high winds rather than excessive snowfall. The most severe stretch included eight blizzard days over an 11-day period, with top wind gusts of 98 km h ⁻¹ . Winds caused severe drifting, covering homes and blocking streets. Broken heavy equipment, including snow-clearing machines, compounded the impacts, leaving homes without essential services like water delivery and sewage pump-out for days. Residents reported the storms and resulting impacts as some of the worst in memory. The drifting and volume of snow, combined with the lack of available resources to manage it, obliged the community to declare a state of emergency. Projections of increased Arctic precipitation and extreme weather events points to the need for communities to have proper resources and supports, including preparedness and adaptation and mitigation strategies, so they can be better equipped to handle storm and blizzard impacts such as those experienced at Clyde River in the winter of 2021/22. Additional steps that can be implemented to better support and prepare communities include investing in preparedness planning, expanded and enhanced weather information and services, community land-based programming to transfer Inuit knowledge and skills, assessing the usefulness of current forecasts, and new approaches to community planning.
Significance Statement
In this study, we consider the winter of 2021/22, during which the community of Clyde River (Kangiqtugaapik), Nunavut experienced 33 days with blizzard conditions—more than any other year since at least 1978/79. Blizzards are characterized by strong winds and blowing snow. Low visibility impedes travel, and drifting snow blocks roads and can bury equipment and buildings. In this case, broken snow-clearing equipment and other infrastructure challenges also hampered the community’s ability to respond, and residents went days without essential services. Several studies suggest that extreme winds will become more common in the Baffin Bay region in the future. This study demonstrates the need for proper resourcing of communities for preparedness, response, and adaptation strategies, especially with the possibility of extreme winter weather becoming more common.
Rapid warming due to human-caused climate change is reshaping the Arctic, enhanced by physical processes that cause the Arctic to warm more quickly than the global average, collectively called Arctic amplification. Observations over the past 40+ years show a transition to a wetter Arctic, with seasonal shifts and widespread disturbances influencing the flora, fauna, physical systems, and peoples of the Arctic.
Arctic rain-on-snow (ROS) events can have significant impacts on Arctic wildlife and socio-economic systems. This study addresses the meteorology of two different Arctic ROS events. The first, occurring near Nuuk, Greenland, generated significant impacts, including slush avalanches. The second, less severe, event occurred within the community of Iqaluit, Nunavut, Canada. This research utilizes atmospheric reanalysis, automated surface observation station data and atmospheric soundings to determine the meteorological conditions driving these events and the differences between each case. In both cases, atmospheric blocking played a leading role in ROS initiation, with atmospheric rivers – narrow bands of high water vapor transport, typically originating from the tropics and subtropics – having both direct and indirect effects. Cyclone-induced low-level jets and resultant ‘warm noses’ of higher air temperatures and moisture transport were other key features in ROS generation. To our knowledge, our study is the first to visualize how the varying strength and manifestation of these coupled features contribute to differences in the severity of Arctic ROS events. The meteorological drivers identified here find support from other studies on Arctic ROS events and are similar to weather features associated with Arctic precipitation events of extreme magnitude.
Given growing interest in extreme high‐latitude weather events, we use records from nine meteorological stations and atmospheric reanalysis data to examine extreme daily precipitation events (leading, 99th and 95th percentile) over Arctic Canada. Leading events span 90 mm at Cape Dyer, along the southeast coast of Baffin Island, to 26 mm at Sachs Harbour, on the southwest coast of Banks Island. The 95th percentiles range from 20 to 30% of leading event sizes. Extreme events are most common on or near the month of climatological peak precipitation. Contrasting with Eurasian continental sites having a July precipitation peak corresponding to the seasonal peak in precipitable water, seasonal cycles in precipitation and the frequency of extremes over Arctic Canada are more varied, reflecting marine influences. At Cape Dyer and Clyde River, mean precipitation and the frequency of extremes peak in October when the atmosphere is quickly cooling, promoting strong evaporation from Baffin Bay. At all stations, leading events involved snowfall and strong winds and were associated with cyclone passages (mostly of relatively strong storms). They also involved strong vapour fluxes, sometimes associated with atmospheric rivers or their remnants. The most unusual sequence of events identified here occurred at Clyde River, where the three largest recorded precipitation events occurred in April of 1977. Obtaining first‐hand accounts of this series of events has proven elusive. Identified links between extreme events and atmospheric rivers demonstrates the need to better understand how the characteristics of such features will change in the future.
Arctic rain on snow (ROS) deposits liquid water onto existing snowpacks. Upon refreezing, this can form icy crusts at the surface or within the snowpack. By altering radar backscatter and microwave emissivity, ROS over sea ice can influence the accuracy of sea ice variables retrieved from satellite radar altimetry, scatterometers, and passive microwave radiometers. During the Arctic Ocean MOSAiC (Multidisciplinary drifting Observatory for the Study of Arctic Climate) expedition, there was an unprecedented opportunity to observe a ROS event using in situ active and passive microwave instruments similar to those deployed on satellite platforms. During liquid water accumulation in the snowpack from rain and increased melt, there was a 4-fold decrease in radar energy returned at Ku- and Ka-bands. After the snowpack refroze and ice layers formed, this decrease was followed by a 6-fold increase in returned energy. Besides altering the radar backscatter, analysis of the returned waveforms shows the waveform shape changed in response to rain and refreezing. Microwave emissivity at 19 and 89 GHz increased with increasing liquid water content and decreased as the snowpack refroze, yet subsequent ice layers altered the polarization difference. Corresponding analysis of the CryoSat-2 waveform shape and backscatter as well as AMSR2 brightness temperatures further shows that the rain and refreeze were significant enough to impact satellite returns. Our analysis provides the first detailed in situ analysis of the impacts of ROS and subsequent refreezing on both active and passive microwave observations, providing important baseline knowledge for detecting ROS over sea ice and assessing their impacts on satellite-derived sea ice variables.
Arctic rain-on-snow (ROS) deposits liquid water onto existing snowpacks. Upon refreezing, this can form icy crusts at the surface or within the snowpack. By altering radar backscatter and microwave emissivity, ROS over sea ice can influence the accuracy of sea ice variables retrieved from satellite radar altimetry, scatterometers, and passive microwave radiometers. During the Arctic Ocean MOSAiC Expedition, there was an unprecedented opportunity to observe a ROS event using in situ active and passive microwave instruments similar to those deployed on satellite platforms. During liquid water accumulation in the snowpack, there was a four-fold decrease in radar energy returned at Ku- and Ka-bands. After the snowpack refroze and ice layers formed, this decrease was followed by a six-fold increase in returned energy. Besides altering the radar backscatter, analysis of the returned waveforms shows the waveform shape changed in response to rain and refreezing. Microwave emissivity at 19 and 89 GHz increased with increasing liquid water content and decreased as the snowpack refroze, yet subsequent ice layers altered the polarization difference. Corresponding analysis of CryoSat-2 waveform shape and backscatter as well as AMSR2 brightness temperatures further shows the rain/refreeze was significant enough to impact satellite returns. Our analysis provides the first detailed in situ analysis of the impacts of ROS and subsequent refreezing on both active and passive microwave observations, providing important baseline knowledge for detecting ROS over sea ice and assessing their impacts on satellite-derived sea ice variables.
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.
... Some Arctic communities have successfully expanded environmental monitoring to meet community information needs (Beaulieu et al., 2023;Bell et al., 2015;Fox et al., 2020) and have established programs for developing relevant decision-support tools, training, and education for travel safety, traditional practices, and subsistence hunting (Beaulieu et al., 2023;Carter et al., 2023;Fox et al., 2020;Panikkar et al., 2018;Sawatzky et al., 2021;Segal et al., 2020;Simonee et al., 2021;Wilson, Arreak, Itulu et al., 2021). Under growing impacts from climate change and prolonged severe weather events, preparedness, training, WWIC services and capacity building are critical to community resilience and adaptation (Fox et al., 2023). Simonee et al. (2021) recommended formalized training of community members to develop local, tailored meteorological services that are relevant and inclusive of local communities, their activities and contexts. ...
... These enhanced high pressure systems, often centered to the south or southeast of the ROS location, act to advect anomalously warm, moist air from lower latitudes into the Arctic. In addition, these high pressure patterns may link ROS events with atmospheric rivers and extreme precipitation events in the Arctic (e.g., Mundhenk et al., 2016;Pettersen et al., 2022;Voveris & Serreze, 2023). Few studies have investigated the synoptic conditions of ROS events in northern Alaska. ...
... One of the essential components of the Arctic climate system is the energy (heat) exchange with lower latitudes [Serreze and Barry, 2014]. The on-going global warming, amplified in the Arctic, is projected to continue in the 21st century [Esau et al., 2023;Koenigk et al., 2012;Liang et al., 2020]. ...
... These changes to total precipitation and the phase of precipitation are extremely important for determining ice sheet and ice shelf SMB. For 570 example, rain-on-snow events can cause the surface to darken, reducing surface albedo and enhancing melt via the melt-albedo feedback (Box et al., 2022;Stroeve et al., 2022). As the climate warms, the future of Antarctic precipitation phase will remain an extremely pertinent subject of research. ...
... Estimating the s-i interface has commonly been achieved by using Ku-band radars, where laboratory experiments have shown that Ku-band signals 45 can penetrate to the s-i interface under cold and dry conditions (Beaven et al., 1995). Based on these experiments, Ku-band signals is often assumed to penetrate the snow cover, providing radar freeboards which are directly converted to sea ice freeboard after accounting for the slower wave propagation speed (e.g., Hendricks, 2022;Rinne and Hendricks, 2023). Several studies 2 https://doi. ...
... Despite the variations among individual models, the CMIP6-ENS projections were consistent with the broader findings of Ruosteenoja and Jylhä, (2022). The projected increase in seasonal precipitation is largely attributed to higher air temperatures, increasing the atmosphere's ability to carry moisture (McCrystall et al., 2021). In addition, the rising surface air temperatures increase evaporation from ice-free ocean and land surfaces, contributing to higher water vapour levels in the atmosphere, further intensifying precipitation (Dou et al., 2022;McCrystall et al., 2021;Yu and Zhong, 2021). ...
... The latest Coupled Model Intercomparison Project (CMIP) climate projection model, CMIP6, projects a 422% increase in rainfall from 2000 -2100 under a high emissions scenario, which is substantially greater than the 260% increase that was predicted by the prior version (CMIP5) 52 . Our study highlights the especially strong potential of atmospheric rivers for creating increasingly extreme snowpack conditions in the future, with substantial implications for northern social-ecological systems 53 . These conditions are especially consequential for wildlife when they occur in the fall, because difficult snowscapes can persist through winter and spring. ...
... In addition to these, increasing temperatures, longer dry spells and more frequent and intense rains put crop and livestock production in Tanzania at risk [28]. A prolonged dry spell in MAM has been significant increase as compared to the OND rain season [29][30][31][32]. Little change in overall rainfall; slight decrease from 1961-2013, mainly from March to June [33]. ...
... While many dynamical and statistical prediction systems have documented "skillful" SIE predictions, it is arguably more important to consider the quantitative level of skill and whether such predictions could provide value to end users (Murphy 1993). The sea ice prediction community gathered for a Sea Ice Outlook Contributors Forum in 2021 where this and many other issues were discussed (Steele et al. 2021). Many workshop attendees expressed a need to rigorously quantify the current state-of-the-art across modern sea ice prediction systems. ...
... For instance, during considerable portions of the winters in 2017 and 2020, the BH and associated Beaufort Gyre-a prominent component of the Arctic sea ice and upper ocean circulationunexpectedly vanished (Moore et al. 2018;Ballinger et al. 2021). The winter of 2020/21 was also highly unusual, and featured an extraordinarily strong BH and the second-highest winter sea-level pressure (SLP) north of 60° N since 1979 that resulted in significant sea ice redistributions in the central Arctic (Mallett et al. 2021). ...