Rapidly changing subglacial hydrology pathways at a tidewater glacier revealed through simultaneous observations of water pressure, supraglacial lakes, meltwater plumes and surface velocities

Penelope How, Douglas I. Benn, Nicholas R. J. Hulton, Bryn Hubbard, Adrian J. Luckman, Heïdi Sevestre, Ward J. J. Van Pelt, Katrin Lindbäck, Jack Kohler, Wim Boot

Research output: Working paperDiscussion paper

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Abstract

Subglacial hydrological processes at tidewater glaciers remain poorly understood due to the difficulty in obtaining direct measurements and lack of empirical verification for modelling approaches. Here, we investigate the subglacial hydrology of Kronebreen, a fast-flowing tidewater glacier in Svalbard during the 2014 melt season. We combine observations of water pressure, supraglacial lake drainage, surface velocities and plume activity with modelled runoff and water routing to develop a conceptual model that thoroughly encapsulates subglacial drainage at a tidewater glacier. Simultaneous measurements suggest that an early-season episode of subglacial flushing took place during our observation period, and a stable efficient drainage system effectively transported this water through the north region of the glacier tongue. Drainage pathways through the central/southern region of the glacier tongue were disrupted throughout the following melt season. Periodic plume activity at the terminus seems to be a signal for modulated subglacial pulsing i.e. an internally-driven storage and release of subglacial meltwater. This storage is a key control on ice flow in the 2014 melt season. Evidence from this work, and previous studies, strongly suggests that long-term changes in ice flow at Kronebreen are controlled by the location of efficient/inefficient drainage and the position of regions where water is stored and evacuated from
Original languageEnglish
Pages1-29
DOIs
Publication statusPublished - 11 May 2017

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