Mapping Surface Flow Velocity of Glaciers at Regional Scale Using a Multiple Sensors Approach

Millan, Romain; Mouginot, J.; Rabatel, Antoine; Jeong, Sang Seom; Cusicanqui, Diego; Derkacheva, Anna; Chekki, Mondher

doi:10.3390/rs11212498

Cited by 89 publications

(128 citation statements)

References 35 publications

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“…Additionally, it is difficult to resolve accurately the SMB gradients of small glaciers <~10 km in length, due to poorer signal-noise relationships and a lack of sufficient data points to accurately predict SMB gradients. The coverage of high-altitude areas and smaller glaciers can be improved in the future with the improvement of optical-satellite-imagery resolution [53] and the enhancement of feature-tracking algorithms.…”

Section: Limitations and Future Directionsmentioning

confidence: 99%

Reversed Surface-Mass-Balance Gradients on Himalayan Debris-Covered Glaciers Inferred from Remote Sensing

et al. 2020

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Meltwater from the glaciers in High Mountain Asia plays a critical role in water availability and food security in central and southern Asia. However, observations of glacier ablation and accumulation rates are limited in spatial and temporal scale due to the challenges that are associated with fieldwork at the remote, high-altitude settings of these glaciers. Here, using a remote-sensing-based mass-continuity approach, we compute regional-scale surface mass balance of glaciers in five key regions across High Mountain Asia. After accounting for the role of ice flow, we find distinctively different altitudinal surface-mass-balance gradients between heavily debris-covered and relatively debris-free areas. In the region surrounding Mount Everest, where debris coverage is the most extensive, our results show a reversed mean surface-mass-balance gradient of −0.21 ± 0.18 m w.e. a−1 (100 m)−1 on the low-elevation portions of glaciers, switching to a positive mean gradient of 1.21 ± 0.41 m w.e. a−1 (100 m)−1 above an average elevation of 5520 ± 50 m. Meanwhile, in West Nepal, where the debris coverage is minimal, we find a continuously positive mean gradient of 1.18 ± 0.40 m w.e. a−1 (100 m)−1. Equilibrium line altitude estimates, which are derived from our surface-mass-balance gradients, display a strong regional gradient, increasing from northwest (4490 ± 140 m) to southeast (5690 ± 130 m). Overall, our findings emphasise the importance of separating signals of surface mass balance and ice dynamics, in order to constrain better their contribution towards the ice thinning that is being observed across High Mountain Asia.

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Section: Limitations and Future Directionsmentioning

confidence: 99%

Reversed Surface-Mass-Balance Gradients on Himalayan Debris-Covered Glaciers Inferred from Remote Sensing

et al. 2020

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“…The mass of the Greenland Ice Sheet is decreasing (e.g., Fettweis et al, 2017;van den Broeke et al, 2017;Wiese et al, 2016;Khan et al, 2016). Most ice sheet mass loss -as ice-berg discharge, submarine melting, and meltwater runoffenters the fjords and coastal seas, and therefore ice sheet mass loss directly contributes to sea-level rise (WCRP Global Sea Level Budget Group, 2018;Moon et al, 2018;Nerem et al, 2018;Chen et al, 2017). Greenland's total ice loss can be estimated through a variety of independent methods, for example direct mass change estimates from GRACE (Wiese et al, 2016), or by using satellite altimetry to estimate surface elevation change, which is then converted into mass change (using a firn model, e.g., Khan et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…However, partitioning the mass loss between ice discharge (D) and surface mass balance (SMB) remains challenging (see Rignot et al, 2008;Enderlin et al, 2014). Correctly assessing mass loss, as well as the attribution of this loss (SMB or D), is critical to understanding the process-level response of the Greenland Ice Sheet to climate change and thus improving models of future ice sheet changes and associated sea-level rise (Moon et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Greenland Ice Sheet solid ice discharge from 1986 through March 2020

Mankoff

Solgaard

Colgan

et al. 2020

Earth Syst. Sci. Data

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Abstract. We present a 1986 through March 2020 estimate of Greenland Ice Sheet ice discharge. Our data include all discharging ice that flows faster than 100 m yr−1 and are generated through an automatic and adaptable method, as opposed to conventional handpicked gates. We position gates near the present-year termini and estimate problematic bed topography (ice thickness) values where necessary. In addition to using annual time-varying ice thickness, our time series uses velocity maps that begin with sparse spatial and temporal coverage and end with near-complete spatial coverage and 12 d updates to velocity. The 2010 through 2019 average ice discharge through the flux gates is ∼487±49 Gt yr−1. The 10 % uncertainty stems primarily from uncertain ice bed location (ice thickness). We attribute the ∼50 Gt yr−1 differences among our results and previous studies to our use of updated bed topography from BedMachine v3. Discharge is approximately steady from 1986 to 2000, increases sharply from 2000 to 2005, and then is approximately steady again. However, regional and glacier variability is more pronounced, with recent decreases at most major glaciers and in all but one region offset by increases in the northwest region through 2017 and in the southeast from 2017 through March 2020. As part of the journal's living archive option and our goal to make an operational product, all input data, code, and results from this study will be updated as needed (when new input data are available, as new features are added, or to fix bugs) and made available at https://doi.org/10.22008/promice/data/ice_discharge (Mankoff, 2020a) and at https://github.com/mankoff/ice_discharge (last access: 6 June 2020, Mankoff, 2020e).

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“…The temporal sampling is a bit counter intuitive, as this is an opposite direction to the workflow of [Millan et al 2019]. Where they found the time-span needs to be of sufficient size, in order to be of most use.…”

Section: Interactive Commentmentioning

confidence: 99%

review of Glacier Image Velocimetry

2020

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The toolbox presented by the authors is a GUI to ease feature tracking routines within a MATLAB environment. The naming of the toolbox is a reference to Particle Image Velocimetry (PIV), which is a well established technique within fluid mechanics. It is based upon particle seeding within a fluid, illuminated by light behind a narrow slit to get a within-plane velocity profile, thus in a well-controlled environment. When particles are not well stirred, have a lot of out-of-plane displacements, too large time separation, or other effects complicating the tracking: the experiment is done all over.

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Mapping Surface Flow Velocity of Glaciers at Regional Scale Using a Multiple Sensors Approach

Cited by 89 publications

References 35 publications

Reversed Surface-Mass-Balance Gradients on Himalayan Debris-Covered Glaciers Inferred from Remote Sensing

Reversed Surface-Mass-Balance Gradients on Himalayan Debris-Covered Glaciers Inferred from Remote Sensing

Greenland Ice Sheet solid ice discharge from 1986 through March 2020

review of Glacier Image Velocimetry

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