Continental heat anomalies and the extreme melting of the Greenland ice surface in 2012 and 1889

Neff, W. D.; Compo, Gilbert P.; Ralph, F. Martin; Shupe, Matthew D.

doi:10.1002/2014jd021470

Cited by 139 publications

(170 citation statements)

References 41 publications

Supporting

Mentioning

159

Contrasting

Order By: Relevance

“…These two periods were associated with passages of strong precipitation events, so-called atmospheric river (AR): poleward moisture was organized in a filamentary structure stretching from subtropical latitudes to Antarctica, leading to heavy snow accumulation events over DML (Gorodetskaya et al 2014). Note that, in Greenland, an AR event was observed in summer 2012 (e.g., Neff et al 2014), including water vapor isotope monitoring (Bonne et al 2015), and let to widespread melt at the ice sheet surface (Nghiem et al 2012). As observed over the Greenland ice sheet, T max rose at Syowa above the melting point during these events.…”

Section: Methodsmentioning

confidence: 99%

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

Kurita

Hirasawa

Koga

et al. 2016

SOLA

View full text Add to dashboard Cite

Warm events, periods when rising surface air temperatures can trigger surface melt, have been recorded during the austral summer at Syowa station on the East Antarctic coast. This study identifies air masses responsible for summer warm events at Syowa. Air masses arriving at Syowa are classified into marine and glacial sources based on their isotopic characteristics. Warm events are not associated with moist marine air intrusion, but with the downward flow of dry glacial air along the west side slope of the mountains in Enderby Land (EL). We use simulations from the Antarctic Mesoscale Prediction System (AMPS) to explore the atmospheric process responsible for the warmest event at Syowa. The model output illustrates several foehn-associated features such as low-level blocking, precipitation on the mountain's windward side, and mountain wave activity, with warm air ascending on the upstream slope and descending to Syowa. The foehn warming is caused by an easterly cross-mountain flow associated with a low-pressure system to the north of the EL coast. Future changes in synoptic cyclonic activity off the EL coast may have a significant impact on the frequency and intensity of foehn events at Syowa and the associated coastal warm events.(Citation: Kurita, N., N. Hirasawa, S. Koga, J. Matsushita, H. C. Steen-Larsen, V. Masson-Delmotte, and Y. Fujiyoshi, 2016: Identification of air mass responsible for warm events on the East

show abstract

Section: Methodsmentioning

confidence: 99%

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

Kurita

Hirasawa

Koga

et al. 2016

SOLA

View full text Add to dashboard Cite

show abstract

“…Several explanations have been put forth to explain this anomalous melt, including increased downwelling longwave radiation from low-level liquid clouds (Bennartz et al, 2013), advection of moist warm air over Greenland (Neff et al, 2014), and dominance of non-radiative fluxes (Fausto et al, 2016). While this event was likely a result of atmospheric circulation patterns that transported warm, humid air over the southern and western part of the ice sheet, the sea ice melt season began a week earlier than the 1981-2010 longterm mean over Davis Strait and 3 days earlier over Baffin Bay.…”

Section: Junementioning

confidence: 99%

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

et al. 2017

View full text Add to dashboard Cite

Abstract. Rapid decline in Arctic sea ice cover in the 21st century may have wide-reaching effects on the Arctic climate system, including the Greenland ice sheet mass balance. Here, we investigate whether local changes in sea ice around the Greenland ice sheet have had an impact on Greenland surface melt. Specifically, we investigate the relationship between sea ice concentration, the timing of melt onset and open-water fraction surrounding Greenland with ice sheet surface melt using a combination of remote sensing observations, and outputs from a reanalysis model and a regional climate model for the period of 1979-2015. Statistical analysis points to covariability between Greenland ice sheet surface melt and sea ice within Baffin Bay and Davis Strait. While some of this covariance can be explained by simultaneous influence of atmospheric circulation anomalies on both the sea ice cover and Greenland melt, within Baffin Bay we find a modest correlation between detrended melt onset over sea ice and the adjacent ice sheet melt onset. This correlation appears to be related to increased transfer of sensible and latent heat fluxes from the ocean to the atmosphere in early sea ice melt years, increasing temperatures and humidity over the ice sheet that in turn initiate ice sheet melt.

show abstract

“…The observed 2012 Greenland melting was attributed to the following key factors: the North American heat wave, transitions in the Arctic Oscillation and transport of warm air and vapour via an atmospheric river (Neff et al, 2014;Bonne et al, 2014). Forcing the model with only oceanic conditions can thus not create a similar atmospheric-induced warming.…”

Section: Influence On Greenland Precipitationmentioning

confidence: 99%

How does sea ice influence <i>δ</i><sup>18</sup>O of Arctic precipitation?

et al. 2017

View full text Add to dashboard Cite

Abstract. This study investigates how variations in Arctic sea ice and sea surface conditions influence δ 18 O of presentday Arctic precipitation. This is done using the model iso-CAM3, an isotope-equipped version of the National Center for Atmospheric Research Community Atmosphere Model version 3. Four sensitivity experiments and one control simulation are performed with prescribed sea surface temperature (SST) and sea ice. Each of the four experiments simulates the atmospheric and isotopic response to Arctic oceanic conditions for selected years after the beginning of the satellite era in 1979.Changes in sea ice extent and SSTs have different impacts in Greenland and the rest of the Arctic. The simulated changes in central Arctic sea ice do not influence δ 18 O of Greenland precipitation, only anomalies of Baffin Bay sea ice. However, this does not exclude the fact that simulations based on other sea ice and sea surface temperature distributions might yield changes in the δ 18 O of precipitation in Greenland. For the Arctic, δ 18 O of precipitation and water vapour is sensitive to local changes in sea ice and sea surface temperature and the changes in water vapour are surface based. Reduced sea ice extent yields more enriched isotope values, whereas increased sea ice extent yields more depleted isotope values. The distribution of the sea ice and sea surface conditions is found to be essential for the spatial distribution of the simulated changes in δ 18 O.

show abstract

Continental heat anomalies and the extreme melting of the Greenland ice surface in 2012 and 1889

Cited by 139 publications

References 41 publications

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

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

How does sea ice influence <i>δ</i><sup>18</sup>O of Arctic precipitation?

Contact Info

Product

Resources

About

Continental heat anomalies and the extreme melting of the Greenland ice surface in 2012 and 1889

Cited by 139 publications

References 41 publications

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

Identification of Air Masses Responsible for Warm Events on the East Antarctic Coast

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

How does sea ice influence &lt;i&gt;δ&lt;/i&gt;&lt;sup&gt;18&lt;/sup&gt;O of Arctic precipitation?

Contact Info

Product

Resources

About

How does sea ice influence <i>δ</i><sup>18</sup>O of Arctic precipitation?