Angela von Deschwanden scite author profile

Abstract. We present a multi-temporal digital inventory of Svalbard glaciers with the most recent from the late 2000s containing 33 775 km 2 of glaciers covering 57 % of the total land area of the archipelago. At present, 68 % of the glacierized area of Svalbard drains through tidewater glaciers that have a total terminus width of ∼ 740 km. The glacierized area over the entire archipelago has decreased by an average of 80 km 2 a −1 over the past ∼ 30 yr, representing a reduction of 7 %. For a sample of ∼ 400 glaciers (10 000 km 2 ) in the south and west of Spitsbergen, three digital inventories are available from the 1930/60s, 1990 and 2007 from which we calculate average changes during 2 epochs. In the more recent epoch, the terminus retreat was larger than in the earlier epoch, while area shrinkage was smaller. The contrasting pattern may be explained by the decreased lateral wastage of the glacier tongues. Retreat rates for individual glaciers show a mix of accelerating and decelerating trends, reflecting the large spatial variability of glacier types and climatic/dynamic response times in Svalbard. Lastly, retreat rates estimated by dividing glacier area changes by the tongue width are larger than centerline retreat due to a more encompassing frontal change estimate with inclusion of lateral area loss.

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Decadal changes from a multi-temporal glacier inventory of Svalbard

Nuth¹,

Kohler²,

König³

et al. 2013

Preprint

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We present a multi-temporal digital inventory of Svalbard glaciers with the most recent from the late 2000s containing 33 775 km² of glaciers, or 57% of the total land area of the archipelago. At present, 68% of the glaciated area of Svalbard drains through tidewater glaciers that have a summed terminus width of ~ 740 km. The glaciated area over the entire archipelago has decreased by an average of 80 km² a⁻¹ over the past ~ 30 yr, representing a reduction of 7%. For a sample of ~ 400 glaciers (10 000 km²) in the south and west of Spitsbergen, three digital inventories are available from 1930/60s, 1990 and 2007 from which we calculate average changes during 2 epochs. In the more recent epoch, the terminus retreat was larger than in the earlier epoch while area shrinkage was smaller. The contrasting pattern may be explained by the decreased lateral wastage of the glacier tongues. Temporal retreat rates for individual glaciers show a mix of accelerating and decelerating trends, reflecting the large spatial variability of glacier types and climatic/dynamic response times in Svalbard. Last, retreat rates estimated by dividing glacier area changes by the tongue width are larger than centerline retreat due to a more encompassing frontal change estimate with inclusion of lateral area loss

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Quantarctica, an integrated mapping environment for Antarctica, the Southern Ocean, and sub-Antarctic islands

Matsuoka

Skoglund

Roth

et al. 2021

Environmental Modelling & Software

155

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Complex network of channels beneath an Antarctic ice shelf

Langley

Deschwanden

Kohler

et al. 2014

Geophysical Research Letters

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Ice shelves play an important role in stabilizing the interior grounded ice of the large ice sheets.The thinning of major ice shelves observed in recent years, possibly in connection to warmer ocean waters coming into contact with the ice-shelf base, has focused attention on the ice-ocean interface. Here we reveal a complex network of sub ice-shelf channels under the Fimbul Ice Shelf, Antarctica, mapped using ground-penetrating radar over a 100 km 2 grid. The channels are 300-500 m wide and 50 m high, among the narrowest of any reported. Observing narrow channels beneath an ice shelf that is mainly surrounded by cold ocean waters, with temperatures close to the surface freezing point, shows that channelized basal melting is not restricted to rapidly melting ice shelves, indicating that spatial melt patterns around Antarctica are likely to vary on scales that are not yet incorporated in ice-ocean models.

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Surface mass balance on Fimbul ice shelf, East Antarctica: Comparison of field measurements and large‐scale studies

et al. 2013

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[1] Many challenges remain for estimating the Antarctic ice sheet surface mass balance (SMB), which represents a major uncertainty in predictions of future sea-level rise. Validating continental scale studies is hampered by the sparse distribution of in situ data. Here we present a 26 year mean SMB of the Fimbul ice shelf in East Antarctica between 1983-2009, and recent interannual variability since 2010. We compare these data to the results of large-scale SMB studies for similar time periods, obtained from regional atmospheric modeling and remote sensing. Our in situ data include ground penetrating radar, firn cores, and mass balance stakes and provide information on both temporal and spatial scales. The 26 year mean SMB on the Fimbul ice shelf varies between 170 and 620 kg m À2 a À1 giving a regional average value of 310 ± 70 kg m À2 a À1 . Our measurements indicate higher long-term accumulation over large parts of the ice shelf compared to the large-scale studies. We also show that the variability of the mean annual SMB, which can be up to 90%, can be a dominant factor in short-term estimates. The results emphasize the importance of using a combination of ground-based validation data, regional climate models, and remote sensing over a relevant time period in order to achieve a reliable SMB for Antarctica.

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