Distributed Global Debris Thickness Estimates Reveal Debris Significantly Impacts Glacier Mass Balance

Rounce, David; Hock, Regine; McNabb, Robert; Millan, Romain; Sommer, Christian; Braun, Matthias; Malz, Philipp; Maussion, Fabien; Mouginot, J.; Seehaus, Thorsten; Shean, David

doi:10.1029/2020gl091311

Cited by 79 publications

(106 citation statements)

References 83 publications

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“…I compare this approach to two recently proposed/published methods from Rowan et al (2021) and Rounce et al (2021).…”

Section: Methods To Estimate Debris Thickness and Sub-debris Meltmentioning

confidence: 99%

“…I also evaluate the approach used by Rounce et al (2021) where debris thickness is estimated using the Hill equation,…”

Section: Methods To Estimate Debris Thickness and Sub-debris Meltmentioning

confidence: 99%

“…I quantify the success of the proposed methods and consider factors that cause method failure, specifically, by indirectly solving for debris layer saturation. I then compare these results to two recently proposed/published methods from Rowan et al (2021) and Rounce et al (2021).…”

Section: Introductionmentioning

confidence: 97%

“…Earth's mountain glaciers are 7.3% debris-covered (Herreid and Pellicciotti, 2020), yet estimates of debris thickness, the key variable governing sub-debris melt rates, are only now being derived at large scales (Kraaijenbrink et al, 2017;Rounce et al, 2021) and their accuracy will benefit from further validation. Debris thickness can be derived from a high density network of excavation point measurements (e.g., Anderson et al, 2021), naturally occurring cross sections (e.g., Nicholson and Mertes, 2017) or ground penetrating radar (e.g., Nicholson et al, 2018); however, these methods are time and resource intensive and impractical at large spatial scales.…”

Section: Introductionmentioning

confidence: 99%

“…Debris thickness can be derived from a high density network of excavation point measurements (e.g., Anderson et al, 2021), naturally occurring cross sections (e.g., Nicholson and Mertes, 2017) or ground penetrating radar (e.g., Nicholson et al, 2018); however, these methods are time and resource intensive and impractical at large spatial scales. Proposed methods to derive debris thickness at wider spatial scales are 1) empirical relations between debris thickness and satellite thermal data (e.g., Ranzi et al, 2004;Mihalcea et al, 2008a;Kraaijenbrink et al, 2017); 2) debris thickness derived from satellite thermal data as the residual of a physically-based surface temperature inversion (Foster et al, 2012;Rounce and McKinney, 2014;Schauwecker et al, 2015); 3) a sub-debris melt inversion (Ragettli et al, 2015;Rounce et al, 2018); and 4), a combination of both a sub-debris melt inversion and a surface temperature inversion (Rounce et al, 2021). While studies using moderate/coarse resolution thermal data acquired from satellites is common, the use of field-based oblique or airborne/unmanned aerial vehicle (UAV) acquired high resolution thermal data is surprisingly rare in glaciology (Hopkinson et al, 2010;Aubry-Wake et al, 2015Herreid and Pellicciotti, 2018;Kraaijenbrink et al, 2018), and none of these studies used their thermal data to explicitly solve for debris thickness and/or glacier melt rates.…”

Section: Introductionmentioning

confidence: 99%

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What Can Thermal Imagery Tell Us About Glacier Melt Below Rock Debris?

Herreid¹

2021

Front. Earth Sci.

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Rock debris on the surface of a glacier can dramatically reduce the local melt rate, where the primary factor governing melt reduction is debris layer thickness. Relating surface temperature to debris thickness is a recurring approach in the literature, yet demonstrations of reproducibility have been limited. Here, I present the results of a field experiment conducted on the Canwell Glacier, Alaska, United States to constrain how thermal data can be used in glaciology. These datasets include, 1) a measured sub-daily “Østrem curve” time-series; 2) a time-series of high resolution thermal images capturing several segments of different debris thicknesses including the measurements from 1); 3) a thermal profile through a 38 cm debris cover; and 4) two Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) satellite thermal images acquired within 2 and 3 min of a field-based thermal camera image. I show that, while clear sky conditions are when space-borne thermal sensors can image a glacier, this is an unfavorable time, limiting the likelihood that different thicknesses of debris will have a unique thermal signature. I then propose an empirical approach to estimate debris thickness and compare it to two recently published methods. I demonstrate that instantaneous calibration is essential in the previously published methods, where model parameters calibrated only 1 h prior to a repeat thermal image return diminished debris thickness estimates, while the method proposed here remains robust through time and does not appear to require re-calibration. I then propose a method that uses a time-series of surface temperature at one location and debris thickness to estimate bare-ice and sub-debris melt. Results show comparable cumulative melt estimates to a recently published method that requires an explicit/external estimate of bare ice melt. Finally, I show that sub-pixel corrections to ASTER thermal imagery can enable a close resemblance to high resolution, field-based thermal imagery. These results offer a deeper insight into what thermal data can and cannot tell us about surface debris properties and glacier melt.

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“…I compare this approach to two recently proposed/published methods from Rowan et al (2021) and Rounce et al (2021).…”

Section: Methods To Estimate Debris Thickness and Sub-debris Meltmentioning

confidence: 99%

“…I also evaluate the approach used by Rounce et al (2021) where debris thickness is estimated using the Hill equation,…”

Section: Methods To Estimate Debris Thickness and Sub-debris Meltmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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What Can Thermal Imagery Tell Us About Glacier Melt Below Rock Debris?

Herreid¹

2021

Front. Earth Sci.

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Glacier Ice Thickness Estimation in Indian Himalaya Using Geophysical Methods

Mishra¹,

and²,

Shankar³

2022

Advances in Remote Sensing Technology and the Three Poles

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Glacier structure influence on Himalayan ice‐front morphology

Peacey

Reynolds

Holt

et al. 2023

Earth Surf Processes Landf

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We investigate the role of glacier structures in controlling ice-front morphology and dynamics of four Himalayan lake-terminating glaciers over a 20-year period.At Imja, Trakarding, Lumdin and Dang Pu glaciers, lake area was mapped between 2000 and 2020 using Landsat 5/7/8 and Sentinel-2 imagery. Discrete glacier flow units were identified, with glacier structures (e.g., open crevasses, transverse structures, longitudinal structures) digitised using the finest resolution panchromatic bands in each year (30, 15, or 10 m). Mapping revealed a distinct pattern of transverse structures towards the terminus of each glacier that influence ice-front position and morphology and are then exploited via iceberg calving events. Our structural analysis also illustrates the role of subsurface conduits in calving events.During subsurface conduit collapse, glacier recession is enhanced, leading to calving along adjacent transverse structures. Furthermore, our analysis shows that ice-front morphology influences the pattern of glacier recession. Ice fronts with distinct ice aprons undergo slower periods of recession than ice fronts with ice cliffs. We conclude that glacier structures are important in determining ice-front morphologies at lake-terminating Himalayan glaciers, and therefore, structural analysis is vital when assessing future ice-front positions and behaviour, as well as rates of glacier recession.

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Distributed Global Debris Thickness Estimates Reveal Debris Significantly Impacts Glacier Mass Balance

Cited by 79 publications

References 83 publications

What Can Thermal Imagery Tell Us About Glacier Melt Below Rock Debris?

What Can Thermal Imagery Tell Us About Glacier Melt Below Rock Debris?

Glacier Ice Thickness Estimation in Indian Himalaya Using Geophysical Methods

Glacier structure influence on Himalayan ice‐front morphology

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