TY - JOUR
T1 - Morphology, flow dynamics and evolution of englacial conduits in cold ice
AU - Kamintzis, Jayne Elizabeth
AU - Irvine-Fynn, Tristram
AU - Holt, Tom
AU - Jones, J P P
AU - Porter, Philip R.
AU - Jennings, Stephen James Arthur
AU - Naegeli, Kathrin
AU - Hubbard, Bryn
N1 - Funding Information:
This work was supported by a Knowledge Economy Skills Scholarship II (KESS II) under Project AU10003, a pan-Wales higher-level skills initiative led by Bangor University on behalf of the HE sector in Wales. It is part funded by the Welsh Government's European Social Fund (ESF) convergence programme for West Wales and the Valleys. Funding was awarded to TDLI-F and JEK, with support from Deri Jones & Associates Ltd. TDLI-F acknowledges The Leverhulme Trust (Grant RF-2018-584/4). All authors recognize additional support from Aberystwyth University (DGES). We also acknowledge the SNSF Mobility Fellowship Grant awarded to KN (Grant P2FRP2/174888). FARO is gratefully acknowledged for the loan of the scanner. Support from the UK NERC Arctic Research Station, Kings Bay AS and associated personnel was gratefully received. James Wake, Paula O'Sullivan and Blair Fyffe are thanked for on-site assistance and field support in 2016, and Nick Cox, Catrin Thomas and Bianca Perren are thanked for on-site assistance and field support in 2017. Norwegian Water Resources and Energy Directorate (NVE) is thanked for provision of runoff data. Sille Myreng kindly provided GPS coordinates for the trench extending from the portal, supraglacial discharge measurements and helpful photographs. We also thank three anonymous reviewers for their constructive comments and recommendations that improved the final version of this paper.
Publisher Copyright:
© 2022 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd.
PY - 2023/2/7
Y1 - 2023/2/7
N2 - Meltwater routing through ice masses exerts a fundamental control over glacier dynamics and mass balance, and proglacial hydrology. However, despite recent advances in mapping drainage systems in cold, Arctic glaciers, direct observations of englacial channels and their flow conditions remain sparse. Here, using Terrestrial Laser Scanning (TLS) surveys of the main englacial channel of cold-based Austre Brøggerbreen (Svalbard), we map and compare an entrance moulin reach (122 m long) and exit portal reach (273 m long). Analysis of channel planforms, longitudinal profiles, cross-sections and morphological features reveals evidence of spatial variations in water flow conditions and channel incision mechanisms, and the presence of vadose, epiphreatic and phreatic conditions. The entrance reach, located at the base of a perennial moulin, was characterised by vadose, uniform, channel lowering at annual timescales, evidenced by longitudinal grooves, whereas the exit portal reach showed both epiphreatic and vadose conditions, along with upstream knickpoint migration at intra-annual timescales. Fine-scale features, including grooves and scallops, were readily quantified from the TLS point cloud, highlighting the capacity of the technique to inform palaeoflow conditions, and reveal how pulses of meltwater from rainfall events may adjust englacial conduit behaviour. With forecasts of increasing Arctic precipitation in the coming decades, and a progressively greater proportion of glaciers comprising cold ice, augmenting the current knowledge of englacial channel morphology is essential to constrain future glacier hydrological system change.
AB - Meltwater routing through ice masses exerts a fundamental control over glacier dynamics and mass balance, and proglacial hydrology. However, despite recent advances in mapping drainage systems in cold, Arctic glaciers, direct observations of englacial channels and their flow conditions remain sparse. Here, using Terrestrial Laser Scanning (TLS) surveys of the main englacial channel of cold-based Austre Brøggerbreen (Svalbard), we map and compare an entrance moulin reach (122 m long) and exit portal reach (273 m long). Analysis of channel planforms, longitudinal profiles, cross-sections and morphological features reveals evidence of spatial variations in water flow conditions and channel incision mechanisms, and the presence of vadose, epiphreatic and phreatic conditions. The entrance reach, located at the base of a perennial moulin, was characterised by vadose, uniform, channel lowering at annual timescales, evidenced by longitudinal grooves, whereas the exit portal reach showed both epiphreatic and vadose conditions, along with upstream knickpoint migration at intra-annual timescales. Fine-scale features, including grooves and scallops, were readily quantified from the TLS point cloud, highlighting the capacity of the technique to inform palaeoflow conditions, and reveal how pulses of meltwater from rainfall events may adjust englacial conduit behaviour. With forecasts of increasing Arctic precipitation in the coming decades, and a progressively greater proportion of glaciers comprising cold ice, augmenting the current knowledge of englacial channel morphology is essential to constrain future glacier hydrological system change.
KW - Arctic
KW - Austre Brøggerbreen
KW - englacial drainage
KW - morphology
KW - Terrestrial Laser Scanning
KW - terrestrial laser scanning
UR - http://www.scopus.com/inward/record.url?scp=85143978773&partnerID=8YFLogxK
U2 - 10.1002/esp.5494
DO - 10.1002/esp.5494
M3 - Article
AN - SCOPUS:85143978773
SN - 0197-9337
VL - 48
SP - 415
EP - 432
JO - Earth Surface Processes and Landforms
JF - Earth Surface Processes and Landforms
IS - 2
ER -