Topographic controls on ice flow and recession for Juneau Icefield (Alaska/British Columbia)

Authors Organisations
  • Bethan Davies(Author)
    Royal Holloway
  • Jacob Bendle(Author)
    University of Northern British Columbia
  • Jonathan Carrivick(Author)
    University of Leeds
  • Robert McNabb(Author)
    Ulster University
  • Christopher McNeil(Author)
    United States Geological Survey
  • Mauri Pelto(Author)
    Nichols College
  • Seth Campbell(Author)
    University of Maine
  • Tom Holt(Author)
  • Jeremy Ely(Author)
    The University of Sheffield
  • Bradley Markle(Author)
    University of Colorado
Type Article
Original languageEnglish
Article number5383
Pages (from-to)2357-2390
Number of pages34
JournalEarth Surface Processes and Landforms
Issue number9
Early online date16 Jun 2022
Publication statusPublished - 15 Jul 2022
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Globally, mountain glaciers and ice caps are losing dramatic volumes of ice. The resultant sea-level rise is dominated by contributions from Alaska. Plateau icefields may be especially sensitive to climate change due to the non-linear controls their topography imparts on their response to climate change. However, Alaskan plateau icefields have been subject to little structural glaciological or regional geomorphological assessment, which makes the controls on their present and former mass balance difficult to ascertain. We inventoried 1050 glaciers and 368 lakes in the Juneau Icefield region for the year 2019. We found that 63 glaciers had disappeared since the 2005 inventory, with a reduction in glacier area of 422 km2 (10.0%). We also present the first structural glaciological and geomorphological map for an entire icefield in Alaska. Glaciological mapping of >20 800 features included crevasses, debris cover, foliation, ogives, medial moraines and, importantly, areas of glacier fragmentation, where glaciers either separated from tributaries via lateral recession (n = 59), or disconnected within areas of former icefalls (n = 281). Geomorphological mapping of >10 200 landforms included glacial moraines, glacial lakes, trimlines, flutes and cirques. These landforms were generated by a temperate icefield during the Little Ice Age (LIA) neoglaciation. These data demonstrate that the present-day outlet glaciers, which have a similar thermal and ice-flow regime, have undergone largely continuous recession since the LIA. Importantly, disconnections occurring within glaciers can separate accumulation and ablation zones, increasing rates of glacier mass loss. We show that glacier disconnections are widespread across the icefield and should be critically taken into consideration when icefield vulnerability to climate change is considered.


  • crevasse, geomorphology, glacier, mass balance, moraine, structural glaciology