Meltwater percolation, impermeable layer formation and runoff buffering on Devon Ice Cap, Canada

Ashmore, David W.; Mair, D.; Burgess, David

doi:10.1017/jog.2019.80

Cited by 9 publications

(9 citation statements)

References 63 publications

(129 reference statements)

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“…Our ice slab thicknesses are thicker than the impermeable thickness threshold of at least 1 m noted by Ashmore et al (2020) and overall similar to the observed thickness of Greenland's ice slabs, which can limit or substantially delay meltwater percolation (Charalampidis et al, 2016;Machguth et al, 2016;MacFerrin et al, 2019). Spatially, the radar response associated with refrozen ice slabs in Zone II is widespread (Fig.…”

Section: Zone Iii: Compact Glacier Icesupporting

confidence: 82%

“…Field-based techniques have expanded our knowledge of melting and refreezing processes in firn (Bell et al, 2008;Sylvestre et al, 2013;Forster et al, 2014;Gascon et al, 2014;Machguth et al, 2016), and their observations are necessary to help validate firn models that are often relied upon for mass balance estimates (Ashmore et al, 2020). Field studies typically utilize some combination of firn cores, snow pits, and ground-based radar (GPR) measurements, which provide in-situ measurements or high resolution remotely sensed observations of the local firn column.…”

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confidence: 99%

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Spatial characterization of near-surface structure and meltwater runoff conditions across Devon Ice Cap from dual-frequency radar reflectivity

Chan

Grima²,

Rutishauser³

et al. 2022

Preprint

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Abstract. Melting and refreezing processes in the firn of Devon Ice Cap control meltwater infiltration and runoff across the ice cap, but their full spatial extent and effect on near-surface structure is difficult to measure with ground-based traverses or existing satellite remote sensing. Here, we derive the coherent component of the near-surface return from airborne ice-penetrating radar over Devon Ice Cap, Canadian Arctic, to characterize firn containing centimeter to meter-thick ice layers (i.e., ice slabs) formed from refrozen meltwater in firn. Comparison with reflectivities using a thin layer reflectivity model, informed by ground-based radar and firn core measurements, indicate that the coherent component is sensitive to the near-surface firn structure composed of quasi-specular ice and firn layers, limited by the bandwidth-constrained radar range resolution. By leveraging their differences in range resolution, we assess the use of dual-frequency airborne ice-penetrating radar to characterize the spatial and vertical near-surface structure of Devon Ice Cap. Our results suggest that average ice slab thickness throughout the Devon Ice Cap percolation zone ranges from 4.2 to 5.6 m. This implies conditions that can enable lateral meltwater runoff and potentially contribute to the total surface runoff routed through supraglacial rivers down glacier. Together with the incoherent component of the surface return previously studied, our dual-frequency approach provides an alternative method for characterizing bulk firn properties, particularly where ground-based and higher frequency radar data are not available.

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Section: Zone Iii: Compact Glacier Icesupporting

confidence: 82%

mentioning

confidence: 99%

Spatial characterization of near-surface structure and meltwater runoff conditions across Devon Ice Cap from dual-frequency radar reflectivity

Chan

Grima²,

Rutishauser³

et al. 2022

Preprint

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“…This is analogous to the ice lens aggregation mechanism proposed for the growth of ice slabs 9 , but in these interior regions, an extreme melt season can be the key catalyst that initiates this aggregation, rather than a multi-year excess melt. This implies that the frequency of extreme melt seasons relative to the rate at which the long-term melt to accumulation ratio allows new pore space and cold content to regenerate above the most recent melt layer 36 can alter the water storage capacity of near-surface firn and its response to ongoing surface melting in the ice sheet interior. This timescale is critical because Greenland has already experienced five recordingbreaking melt seasons since 2000 17,[37][38][39][40] , with the 2019 season second only to 2012 in total melt extent 40 .…”

Section: Resultsmentioning

confidence: 99%

Extreme melt season ice layers reduce firn permeability across Greenland

2021

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Surface meltwater runoff dominates present-day mass loss from the Greenland Ice Sheet. In Greenland’s interior, porous firn can limit runoff by retaining meltwater unless perched low-permeability horizons, such as ice slabs, develop and restrict percolation. Recent observations suggest that such horizons might develop rapidly during extreme melt seasons. Here we present radar sounding evidence that an extensive near surface melt layer formed following the extreme melt season in 2012. This layer was still present in 2017 in regions up to 700 m higher in elevation and 160 km further inland than known ice slabs. We find that melt layer formation is driven by local, short-timescale thermal and hydrologic processes in addition to mean climate state. These melt layers reduce vertical percolation pathways, and, under appropriate firn temperature and surface melt conditions, encourage further ice aggregation at their horizon. Therefore, the frequency of extreme melt seasons relative to the rate at which pore space and cold content regenerates above the most recent melt layer may be a key determinant of the firn’s multi-year response to surface melt.

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“…The effective permeability of ice layers and the relation to ice layer thickness is an open question. There is evidence that thick ice layers in firn can be impermeable (Ashmore et al, 2020; Gascon et al, 2013), but meltwater infiltration through ice layers has also been observed or inferred (Ashmore et al, 2020; Humphrey et al, 2012; Machguth et al, 2016). Direct observations are needed to understand these processes and their efficacy with thicker ice layers, as found in the lower percolation zone of Greenland (MacFerrin et al, 2019; Machguth et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…The extent to which meltwater retention in firn can buffer mass loss and sea level rise is also unclear. Greenland's firn zone covers about 80% of the ice sheet, but refrozen near‐surface ice layers have the potential to act as impermeable barriers, redirecting meltwater percolation into runoff (Ashmore et al, 2020; Gascon et al, 2013; MacFerrin et al, 2019; Noël et al, 2017). In the percolation zone, firn densification associated with warming and refreezing is also leading to a loss of available pore space, imposing further limits on meltwater storage capacity as melting progresses inland (Vandecrux et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Meltwater Penetration Through Temperate Ice Layers in the Percolation Zone at DYE‐2, Greenland Ice Sheet

Samimi

Marshall

MacFerrin

2020

Geophysical Research Letters

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Meltwater retention in the firn layer of the Greenland Ice Sheet has the potential to buffer sea level rise due to ice sheet melt. The capacity of the firn layer to store meltwater is unclear, however, because refrozen ice layers can act as impermeable barriers to meltwater percolation, promoting runoff rather than retention. We present time domain reflectometry and thermistor data, which demonstrate that meltwater successfully penetrates ice layers up to 12 cm thick in the near‐surface firn at DYE‐2, Greenland. Our observations indicate that ice layers within polar firn can be permeable when summer warming and latent heat release from meltwater refreezing raise firn temperatures to the melting point. The extent and depth of refreezing, as determined by the coupled thermodynamic and hydrological evolution in the firn, are more important than the presence of ice layers in governing meltwater infiltration and retention at our study site.

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Meltwater percolation, impermeable layer formation and runoff buffering on Devon Ice Cap, Canada

Cited by 9 publications

References 63 publications

Spatial characterization of near-surface structure and meltwater runoff conditions across Devon Ice Cap from dual-frequency radar reflectivity

Spatial characterization of near-surface structure and meltwater runoff conditions across Devon Ice Cap from dual-frequency radar reflectivity

Extreme melt season ice layers reduce firn permeability across Greenland

Meltwater Penetration Through Temperate Ice Layers in the Percolation Zone at DYE‐2, Greenland Ice Sheet

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