Investigating the local-scale influence of sea ice on Greenland surface melt

Stroeve, Julienne; Mioduszewski, J.; Rennermalm, Å. K.; Boisvert, Linette N.; Tedesco, Marco; Robinson, David A.

doi:10.5194/tc-11-2363-2017

Cited by 27 publications

(34 citation statements)

References 78 publications

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“…A wide range of approaches have previously indicated that Baffin Bay sea ice changes impact conditions on Greenland. Rennermalm et al () and Stroeve et al () present process‐based analyses linking sea ice loss through changed surface fluxes to increased melt on GrIS. In agreement with the signals we see along the west coast (Figure ), both of these studies find that sea ice loss in Baffin Bay promotes melting on the adjacent parts of the ice sheet.…”

Section: Resultsmentioning

confidence: 99%

“…The long-term view employed here is inspired by detection and attribution studies used, for example, in the context of the Intergovernmental Panel on Climate Change (Bindoff et al, 2013). It is meant to supplement process-based analyses (e.g., Rennermalm et al, 2009;Stroeve et al, 2017), attempting to reveal covariability between changes in different parts of Greenland and the state of the sea ice cover and the state of the global climate, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…expectation that sea ice loss is a key contributor to amplified Arctic warming (Dai et al, 2019;Screen & Simmonds, 2010;Serreze & Barry, 2011), the still short observational record of the Arctic sea ice cover change makes it challenging to show direct links between sea ice loss and warming over Greenland. Previous studies have focused on process-based attribution using lagged correlations to trace the sequence of events from sea ice reduction to increased warming or melt on the ice sheet (e.g., Ballinger et al, 2018;Rennermalm et al, 2009;Stroeve et al, 2017). Here, we use a linear framework, aiming to separate the simulated warming in two contributions: one following the global warming trend and one following the Arctic sea ice conditions.…”

Section: Introductionmentioning

confidence: 99%

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Attributing Greenland Warming Patterns to Regional Arctic Sea Ice Loss

Pedersen

Christensen

2019

Geophysical Research Letters

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Observed and model‐projected sea ice loss enhances warming in the Arctic. We investigate to what extent warming on Greenland can be attributed to changes in the sea ice cover in different parts of the Arctic. Using Climate Model Intercomparison Project phase 5 model projections of the future, we perform multilinear regressions to separate the simulated warming on Greenland in two parts; one following global warming and one following regional sea ice changes. This reveals the magnitude and spatial pattern of warming on Greenland, which can be attributed to sea ice loss in different Arctic regions. The results indicate that the impact of sea ice loss is largely confined to the coastal parts of Greenland. We find the strongest links to sea ice loss in adjacent regions; remote regions only have a limited impact. Overall, warming attributable to sea ice variability is a minor contribution but can be a dominant signal locally in coastal regions.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Attributing Greenland Warming Patterns to Regional Arctic Sea Ice Loss

Pedersen

Christensen

2019

Geophysical Research Letters

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“…In summer, the polar vortex is slightly weaker in CESM2, with its central geopotential height overestimated by 2 dams (Figure f), although the southward expansion of the polar vortex appears exaggerated. September sea ice extent is slightly underestimated in CESM2 (Figure e), but there is good agreement near Greenland, suggesting that substantial GrIS SMB biases due to sea ice biases are unlikely (Noël et al, ; Stroeve et al, ).…”

Section: Resultsmentioning

confidence: 95%

Present‐Day Greenland Ice Sheet Climate and Surface Mass Balance in CESM2

et al. 2020

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The response of the Greenland Ice Sheet (GrIS) to a warmer climate is uncertain on long time scales. Climate models, such as those participating in the Coupled Model Intercomparison Project phase 6 (CMIP6), are used to assess this uncertainty. The Community Earth System Model version 2.1 (CESM2) is a CMIP6 model capable of running climate simulations with either one‐way coupling (fixed ice sheet geometry) or two‐way coupling (dynamic geometry) to the GrIS. The model features prognostic snow albedo, online downscaling using elevation classes, and a firn pack to refreeze percolating melt water. Here we evaluate the representation of the GrIS surface energy balance and surface mass balance in CESM2 at 1° resolution with fixed GrIS geometry. CESM2 agrees closely with ERA‐Interim reanalysis data for key controls on GrIS SMB: surface pressure, sea ice extent, 500 hPa geopotential height, wind speed, and 700 hPa air temperature. Cloudsat‐CALIPSO data show that supercooled liquid‐containing clouds are adequately represented, whereas comparisons to Moderate Resolution Imaging Spectroradiometer and CM SAF Cloud, Albedo, and Surface Radiation data set from Advanced Very High Resolution Radiometer data second edition data suggest that CESM2 underestimates surface albedo. The seasonal cycle and spatial patterns of surface energy balance and surface mass balance components in CESM2 agree well with regional climate model RACMO2.3p2, with GrIS‐integrated melt, refreezing, and runoff bracketed by RACMO2 counterparts at 11 and 1 km. Time series of melt, runoff, and SMB show a break point around 1990, similar to RACMO2. These results suggest that GrIS SMB is realistic in CESM2, which adds confidence to coupled ice sheet‐climate experiments that aim to assess the GrIS contribution to future sea level rise.

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“…For example, sea ice loss is projected to continue, including periods of especially rapid change (e.g., Holland et al, 2006; rapid declines already occurred in 2007 and 2012; Stroeve et al, 2012). Rapid sea ice loss not only heightens atmospheric warming, but also early loss of sea ice locally near the Greenland Ice Sheet may increase heat transfer from the ocean to the atmosphere above the ice sheet and result in increased ice sheet melt (Stroeve et al, 2017). Rapid sea ice loss also has a significant effect on temperatures over land with implications for permafrost thaw (Lawrence et al, 2008), and increased wave activity due to sea ice loss can also lead to stronger permafrost coastal erosion, further exacerbated by sea level rise from land ice loss (Fritz et al, 2017).…”

Section: Connections Across the Arctic Systemmentioning

confidence: 99%

The Expanding Footprint of Rapid Arctic Change

et al. 2019

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Arctic land ice is melting, sea ice is decreasing, and permafrost is thawing. Changes in these Arctic elements are interconnected, and most interactions accelerate the rate of change. The changes affect infrastructure, economics, and cultures of people inside and outside of the Arctic, including in temperate and tropical regions, through sea level rise, worsening storm and hurricane impacts, and enhanced warming. Coastal communities worldwide are already experiencing more regular flooding, drinking water contamination, and coastal erosion. We describe and summarize the nature of change for Arctic permafrost, land ice, and sea ice, and its influences on lower latitudes, particularly the United States. We emphasize that impacts will worsen in the future unless individuals, businesses, communities, and policy makers proactively engage in mitigation and adaptation activities to reduce the effects of Arctic changes and safeguard people and society.

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Investigating the local-scale influence of sea ice on Greenland surface melt

Cited by 27 publications

References 78 publications

Attributing Greenland Warming Patterns to Regional Arctic Sea Ice Loss

Attributing Greenland Warming Patterns to Regional Arctic Sea Ice Loss

Present‐Day Greenland Ice Sheet Climate and Surface Mass Balance in CESM2

The Expanding Footprint of Rapid Arctic Change

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