Multiple Effects of Changes in Arctic Snow Cover

Callaghan, Terry V.; Johansson, Margareta; Brown, Ross; Groisman, P. Y.; Labba, Niklas; Радионов, В. Ф.; Bradley, Raymond S.; Blangy, Sylvie; Bulygina, Olga; Christensen, Torben R.; Colman, Jonathan E.; Essery, Richard; Forbes, Bruce C.; Forchhammer, Mads C.; Голубев, В. А.; Honrath, R. E.; Juday, Glenn P.; Meshcherskaya, Anna V.; Phoenix, Gareth K.; Pomeroy, John W.; Rautio, Arja; Robinson, David A.; Schmidt, Niels Martin; Serreze, Mark C.; Шевченко, В. П.; Shiklomanov, A. I.; Шмакин, А. Б.; Sköld, Peter; Sturm, Matthew; Woo, Ming Ko; Wood, Eric F.

doi:10.1007/s13280-011-0213-x

Cited by 182 publications

(122 citation statements)

References 81 publications

(74 reference statements)

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“…Open water in this relatively warm oceanic area would be consistent with enhanced storminess and increased snowfall during spring or fall that could reduce TI-NDVI. Snow cover simulations from several reanalysis-driven snow cover reconstructions suggest increasing trends in annual maximum snow accumulation on Svalbard and Franz Josef Land over the past 30 years [60] which is consistent with observed increases in cold season precipitation over the Barents Sea sector of the Arctic and increases in winter snow depths over northern Eurasia [61].…”

Section: Regional Trends and Variabilitysupporting

confidence: 66%

Recent Declines in Warming and Vegetation Greening Trends over Pan-Arctic Tundra

et al. 2013

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Section: Regional Trends and Variabilitysupporting

confidence: 66%

Recent Declines in Warming and Vegetation Greening Trends over Pan-Arctic Tundra

et al. 2013

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“…For instance, it has a strong control on the surface energy exchange with the atmosphere, represents an important storage of water that is released during the spring melt period, and affects ground thermal regimes and surface vegetation through its insulating properties. Changes and variability in snow cover therefore have a large impact on many other Earth system processes in these regions, and feedbacks with the climate system can intensify local and regional patterns of change and have global implications (Callaghan et al, 2011b). Snowpack evolution is closely linked with climatic elements such as air temperature and precipitation, and interannual variations and trends in snow cover conditions coincide strongly with those of such climate variables.…”

Section: Contextmentioning

confidence: 99%

Recent climatic, cryospheric, and hydrological changes over the interior of western Canada: a review and synthesis

DeBeer

Wheater

Carey

et al. 2016

Hydrol. Earth Syst. Sci.

101

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Abstract. It is well established that the Earth's climate system has warmed significantly over the past several decades, and in association there have been widespread changes in various other Earth system components. This has been especially prevalent in the cold regions of the northern midto high latitudes. Examples of these changes can be found within the western and northern interior of Canada, a region that exemplifies the scientific and societal issues faced in many other similar parts of the world, and where impacts have global-scale consequences. This region has been the geographic focus of a large amount of previous research on changing climatic, cryospheric, and hydrological regimes in recent decades, while current initiatives such as the Changing Cold Regions Network (CCRN) introduced in this review seek to further develop the understanding and diagnosis of this change and hence improve the capacity to predict future change. This paper provides a comprehensive review of the observed changes in various Earth system components and a concise and up-to-date regional picture of some of the temporal trends over the interior of western Canada since the mid-or late 20th century. The focus is on air temperature, precipitation, seasonal snow cover, mountain glaciers, permafrost, freshwater ice cover, and river discharge. Important long-term observational networks and data sets are described, and qualitative linkages among the changing components are highlighted. Increases in air temperature are the most notable changes within the domain, rising on average 2 • C throughout the western interior since 1950. This increase in air temperature is associated with hydrologically important changes to precipitation regimes and unambiguous declines in snow cover depth, persistence, and spatial extent. Consequences of warming air temperatures have caused mountain glaciers to recede at all latitudes, permafrost to thaw at its southern limit, and active layers over permafrost to thicken. Despite these changes, integrated effects on stream flow are complex and often offsetting. Following a review of the current literature, we provide insight from a network of northern research catchments and other sites detailing how climate change confounds hydrological responses at smaller scales, and we recommend several priority research areas that will be a focus of continued work in CCRN. Given the complex interactions and process responses to climate change, it is argued that further conceptual understanding and quantitative diagnosis of the mechanisms of change over a range of scales is required before projections of future change can be made with confidence.

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“…The disappearance of the snow and related increase in surface heating mark the transition into a convective summertype precipitation regime (Callaghan et al, 2011b), which initiates a rapid and distinct change in both plant metabolism and surface energy balance. Ongoing and predicted climate change, however, promotes an increase in atmospheric moisture, winter snowfall over land areas (Rawlins et al, 2010) and variability in the amount of snowfall (Callaghan et al, 2005;Kattsov et al, 2005;Stocker et al, 2013) while higher temperatures stimulate an earlier snowmelt and transition to convective precipitation patterns (Groisman et al, 1994).…”

Section: Snow Cover and Surface Energy Budgetmentioning

confidence: 99%

Two years with extreme and little snowfall: effects on energy partitioning and surface energy exchange in a high-Arctic tundra ecosystem

et al. 2016

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Abstract. Snow cover is one of the key factors controlling Arctic ecosystem functioning and productivity. In this study we assess the impact of strong variability in snow accumulation during 2 subsequent years (2013-2014) on the landatmosphere interactions and surface energy exchange in two high-Arctic tundra ecosystems (wet fen and dry heath) in Zackenberg, Northeast Greenland. We observed that recordlow snow cover during the winter 2012/2013 resulted in a strong response of the heath ecosystem towards low evaporative capacity and substantial surface heat loss by sensible heat fluxes (H ) during the subsequent snowmelt period and growing season. Above-average snow accumulation during the winter 2013/2014 promoted summertime ground heat fluxes (G) and latent heat fluxes (LE) at the cost of H . At the fen ecosystem a more muted response of LE, H and G was observed in response to the variability in snow accumulation. Overall, the differences in flux partitioning and in the length of the snowmelt periods and growing seasons during the 2 years had a strong impact on the total accumulation of the surface energy balance components. We suggest that in a changing climate with higher temperature and more precipitation the surface energy balance of this high-Arctic tundra ecosystem may experience a further increase in the variability of energy accumulation, partitioning and redistribution.

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Multiple Effects of Changes in Arctic Snow Cover

Cited by 182 publications

References 81 publications

Recent Declines in Warming and Vegetation Greening Trends over Pan-Arctic Tundra

Recent Declines in Warming and Vegetation Greening Trends over Pan-Arctic Tundra

Recent climatic, cryospheric, and hydrological changes over the interior of western Canada: a review and synthesis

Two years with extreme and little snowfall: effects on energy partitioning and surface energy exchange in a high-Arctic tundra ecosystem

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