Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-23T21:01:41.032Z Has data issue: false hasContentIssue false

Progress toward globally complete frontal ablation estimates of marine-terminating glaciers

Published online by Cambridge University Press:  29 June 2023

William Kochtitzky*
Affiliation:
School of Marine and Environmental Programs, University of New England, Biddeford, Maine, USA
Luke Copland
Affiliation:
Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario, Canada
Wesley Van Wychen
Affiliation:
Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario, Canada Department of Geography and Environmental Management, University of Waterloo, Waterloo, Ontario, Canada
Regine Hock
Affiliation:
Department of Geosciences, University of Oslo, Oslo, Norway Geophysical Institute, University of Alaska Fairbanks, Fairbanks, Alaska, USA
David R. Rounce
Affiliation:
Department of Civil and Environmental Engineering, Carnegie Mellon University, Pittsburgh, Pennsylvania, USA
Hester Jiskoot
Affiliation:
Department of Geography & Environment, University of Lethbridge, Lethbridge, Alberta, Canada
Ted A. Scambos
Affiliation:
Earth Science Observation Center, CIRES, University of Colorado Boulder, Boulder, Colorado, USA
Mathieu Morlighem
Affiliation:
Department of Earth Sciences, Dartmouth College, Hanover, New Hampshire, USA
Michalea King
Affiliation:
Applied Physics Laboratory, University of Washington, Seattle, WA, USA
Leo Cha
Affiliation:
School of Marine and Environmental Programs, University of New England, Biddeford, Maine, USA
Luke Gould
Affiliation:
School of Marine and Environmental Programs, University of New England, Biddeford, Maine, USA
Paige-Marie Merrill
Affiliation:
School of Marine and Environmental Programs, University of New England, Biddeford, Maine, USA
Andrey Glazovsky
Affiliation:
Institute of Geography, Russian Academy of Sciences, Moscow, Russia
Romain Hugonnet
Affiliation:
LEGOS, Université de Toulouse, CNES, CNRS, IRD, UPS, Toulouse, France Laboratory of Hydraulics, Hydrology and Glaciology (VAW), ETH Zürich, Zürich, Switzerland Swiss Federal Institute for Forest, Snow and Landscape Research (WSL), Birmensdorf, Switzerland
Tazio Strozzi
Affiliation:
Gamma Remote Sensing, Gümligen, BE, Switzerland Department of Geography, Laboratoire de Climatologie et Topoclimatologie, University of Liège, Liège, Belgium
Brice Noël
Affiliation:
Department of Geography, Laboratoire de Climatologie et Topoclimatologie, University of Liège, Liège, Belgium Institute for Marine and Atmospheric Research Utrecht, Utrecht University, Utrecht, The Netherlands
Francisco Navarro
Affiliation:
Departamento de Matemática Aplicada a las TIC, Universidad Politécnica de Madrid, Madrid, Spain
Romain Millan
Affiliation:
Institut des Géosciences de l'Environnement, CNES, Grenoble, France
Julian A. Dowdeswell
Affiliation:
Scott Polar Research Institute, University of Cambridge, Cambridge, UK
Alison Cook
Affiliation:
Scottish Association for Marine Science, Oban, UK
Abigail Dalton
Affiliation:
Department of Geography, Environment and Geomatics, University of Ottawa, Ottawa, Ontario, Canada
Shfaqat Khan
Affiliation:
DTU Space, Technical University of Denmark, Kongens Lyngby, Denmark
Jacek Jania
Affiliation:
University of Silesia, Katowice, Poland
*
Corresponding author: William Kochtitzky; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Knowledge of frontal ablation from marine-terminating glaciers (i.e., mass lost at the calving face) is critical for constraining glacier mass balance, improving projections of mass change, and identifying the processes that govern frontal mass loss. Here, we discuss the challenges involved in computing frontal ablation and the unique issues pertaining to both glaciers and ice sheets. Frontal ablation estimates require numerous datasets, including glacier terminus area change, thickness, surface velocity, density, and climatic mass balance. Observations and models of these variables have improved over the past decade, but significant gaps and regional discrepancies remain, and better quantification of temporal variability in frontal ablation is needed. Despite major advances in satellite-derived large-scale datasets, large uncertainties remain with respect to ice thickness, depth-averaged velocities, and the bulk density of glacier ice close to calving termini or grounding lines. We suggest ways in which we can move toward globally complete frontal ablation estimates, highlighting areas where we need improved datasets and increased collaboration.

Type
Letter
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The International Glaciological Society

1. Introduction

Frontal ablation of water-terminating glaciers is defined as the mass lost at the near-vertical calving front and includes calving, subaerial melting, sublimation, and subaqueous melting (Cogley and others, Reference Cogley2011). The sum of frontal ablation and climatic-basal balance make up the total mass balance of a glacier or ice sheet (Cogley and others, Reference Cogley2011), although only the mass lost above flotation will contribute to sea level rise. Accurate quantification of frontal ablation and its separate components is needed to inform mass balance estimates and associated contributions to sea level and characterize the relative importance of the processes involved (e.g., Huss and Hock, Reference Huss and Hock2015; Rignot and others, Reference Rignot2016; Moon and others, Reference Moon, Gardner, Csatho, Parmuzin and Fahnestock2020). Frontal ablation is currently an important component of the mass budget of glaciers and ice sheets, and is thus essential for models and process understanding of glacier evolution (e.g. Rignot and others, Reference Rignot2016; Aschwanden and others, Reference Aschwanden2019; Catania and others, Reference Catania, Stearns, Moon, Enderlin and Jackson2020), and other applications such as assessing risks to marine activities from icebergs (Obisesan and Sriramula, Reference Obisesan and Sriramula2018; Lee and Park, Reference Lee and Park2021), fresh water inputs to the ocean (e.g., Flexas and others, Reference Flexas, Thompson, Schodlok, Zhang and Speer2022) and changes in marine ecosystems (Ingels and others, Reference Ingels2021). Thus, we need methodologically consistent and globally complete estimates of frontal ablation of glaciers and ice sheets.

At present, frontal ablation estimates for entire glacier regions are available for Alaska (McNabb and others, Reference McNabb, Hock and Huss2015), Patagonia (Minowa and others, Reference Minowa, Schaefer, Sugiyama, Sakakibara and Skvarca2021), two subantarctic islands (King George Island (Osmanoǧlu and others, Reference Osmanoǧlu, Braun, Hock and Navarro2013) and Livingston Island (Osmanoǧlu and others, Reference Osmanoǧlu, Navarro, Hock, Braun and Corcuera2014)). Recently, Kochtitzky and others (Reference Kochtitzky2022, Reference KochtitzkyIn Review) computed frontal ablation for all glaciers in the Northern Hemisphere and found a loss of 522 ± 17 Gt a−1 from 2000 to 2010, increasing to 559 ± 13 Gt a−1 from 2010 to 2020, with ~90% originating from the Greenland Ice Sheet (Fig. 1). This is greater than the combined net mass loss rate of 224 Gt a−1 for Northern Hemisphere glaciers (outside the Greenland Ice Sheet) from 2000–2020 (Hugonnet and others, Reference Hugonnet2021) and 290 Gt a−1 for the Greenland Ice Sheet from 2010–2018 (Mouginot and others, Reference Mouginot2019) over these periods, indicating that the climatic-basal mass balance of all Northern Hemisphere land ice masses was positive. In other words, if no frontal ablation had occurred there would have been a mass gain.

Figure 1. (a) Frontal ablation of all marine-terminating glaciers in the Northern Hemisphere for 2010-2020. Each point shows the location of one glacier. Glaciers with frontal ablation rates <1 Gt a−1 are shown in blue, with larger contributions shown as yellow to red. The size of each circle corresponds to the total frontal ablation. (b) Frontal ablation intensity index along the coastline of each region. We define the frontal ablation intensity index as the sum of frontal ablation from all glaciers within 80 km (Greenland) and 50 km (everywhere else) of a given location. This highlights parts of the ocean that receive the most frontal ablation. Data from Kochtitzky and others (Reference Kochtitzky2022, Reference KochtitzkyIn Review).

Here we outline current challenges in quantifying past frontal ablation for glaciers and ice sheets from observations, highlight datasets that need improvement, and describe the most immediate steps needed to globally complete frontal ablation estimates, including all glaciers and ice sheets. We further emphasize areas where increased collaboration is needed across geographies and methodologies.

2. Current challenges in frontal ablation estimates

Measuring frontal ablation is difficult because the glacier terminus is the most dynamic part of marine-terminating glaciers. Thus, quantifying individually all four physical processes – calving, subaerial melting, subaqueous melting, and subaerial sublimation (Cogley and others, Reference Cogley2011) – at the calving face has not been completed by any study to date. However, several studies have quantified the important role of submarine melt in total frontal ablation at grounded marine-terminating termini. For example, Motyka and others (Reference Motyka, Hunter, Echelmeyer and Connor2003) found that more than half of the estimated total mass loss at the calving front of LeConte glacier in Alaska occurred by melt with the remainder from calving, which was later corroborated with multibeam sonar surveys (Sutherland and others, Reference Sutherland2019). However, most studies (e.g., Osmanoǧlu and others, Reference Osmanoǧlu, Braun, Hock and Navarro2013; King and others, Reference King2018, Reference King2020; Mankoff and others, Reference Mankoff2020; Minowa and others, Reference Minowa, Schaefer, Sugiyama, Sakakibara and Skvarca2021; Kochtitzky and others, Reference Kochtitzky2022) rely on a flux gate approach, computing the ice discharge through an arbitrary cross-section some distance upstream of the terminus or at the grounding line, based on estimates of ice surface velocity and ice thickness.

The flux-gate approach requires the calculation of two components of frontal ablation ($\dot{A}_f$; Eqn (1); Kochtitzky and others, Reference Kochtitzky2022): (1) ice discharge ($\dot{D}_{ice}$) due to ice motion (computed through a flux gate near the terminus; Eqn (2)) and (2) mass change due to retreat or advance of the terminus $( \dot{M}_{term})$ during the considered period (Δt; Eqn (3)). For the first component we need flux gate length (d n), depth-averaged ice velocity perpendicular to the fluxgate (V n), ice density (ρ), and ice thickness (H n) at points n along the flux gate. For the second component we need the total area lost or gained (ΔS term) over Δt and its average thickness $( \bar{H})$ and density. To partition the mass flux properly, both components also need to be corrected for mass change due to the climatic-basal mass balance ($\dot{B}$) over the area down-glacier from the most retreated flux gate (S f; component 1) and the area that may have been lost or gained (ΔS term; component 2).

(1)$$\dot{A}_f = \dot{D}_{ice} + \dot{M}_{term}$$
(2)$$\dot{D}_{ice} = \left(\rho{\left({\mathop \sum \limits_{n = 1}^N ( {V_n\cdot H_n\cdot d_n} ) } \right)-( {S_f\cdot \dot{B}} ) } \right)$$
(3)$$\dot{M}_{term} = \left({\rho \cdot \displaystyle{{\Delta S_{term}} \over {\Delta t}}\cdot \bar{H} + \Delta S_{term}/2\cdot \dot{B}} \right)$$

While some frontal ablation studies have neglected the mass change due to calving front variations (e.g., Van Wychen and others, Reference Van Wychen2014; King and others, Reference King2018; Mankoff and others, Reference Mankoff2020; Bollen and others, Reference Bollen, Enderlin and Muhlheim2022), recent studies of glaciers and the Greenland Ice Sheet quantify both components separately (Minowa and others, Reference Minowa, Schaefer, Sugiyama, Sakakibara and Skvarca2021; Kochtitzky and others, Reference Kochtitzky2022, Reference KochtitzkyIn Review). However, all these studies neglect basal melt down-glacier of the flux gate, which is a reasonable assumption for grounded marine-terminating glaciers but could be problematic for the few remaining ice shelves or floating glacier tongues in the Arctic (Dowdeswell and Jeffries, Reference Dowdeswell and Jeffries2017), and is very problematic for large Antarctic ice shelves with high basal melt rates that account for more mass loss than from calving (Depoorter and others, Reference Depoorter2013; Rignot and others, Reference Rignot, Jacobs, Mouginot and Scheuchl2013). Whereas many datasets included in frontal ablation calculations have improved in recent years, there are still large knowledge gaps we need to address to improve and complete global frontal ablation estimates. Below we highlight each component of frontal ablation and the steps needed to improve the datasets used in these calculations.

2.1 Glacier inventory

Glacier inventories form the basis of large-scale observational and modeling studies. Inventories give us a common basis to identify and describe glaciers to ensure that studies are consistent with each other and seperate glaciers by type (e.g., attached or not to an ice sheet). Frontal ablation studies rely on accurate mapping and attribution of marine-terminating glaciers to inform glacier identification, terminus changes, flux gate placement, area calculations, and more. In this section, we outline current shortcomings of glacier inventories and suggest improvements, specifically in the ways in which they inform frontal ablation studies.

The Randolph Glacier Inventory (RGI) provides the best global inventory of glacier outlines outside the ice sheets, and its compilation involved a monumental and ongoing community effort (Pfeffer and others, Reference Pfeffer2014; RGI Consortium, 2017). RGI prioritizes outlines that are as close to the year 2000 as possible to improve the temporal consistency across the dataset, although this is not always possible (Pfeffer and others, Reference Pfeffer2014). Version 6.0 of the RGI was released in July 2017, and Version 7.0 is in preparation as of April 2023.

The RGI needs further improvement, particularly in improving the consistency of outlines across regions (Fig. 2). For example, Kochtitzky and others (Reference Kochtitzky2022) found 126 marine-terminating glaciers in RGI v6.0 in the Northern Hemisphere that have one outline, and thus one ID, but with at least two distinct termini, which typically originate from different accumulation zones (example in Fig. 2a). In the Russian Arctic and the Antarctic periphery, some ice caps with radial flow have subdivided basins while others do not (Figs 2b and 2c). Other glaciers, such as those in northern Greenland (Fig. 2d), have significant inaccuracies in geometry, which can be corrected with available imagery (e.g., see Ochwat and others, Reference Ochwat, Scambos, Fahnestock and Stammerjohn2022). The RGI v6.0 does not correctly identify all marine-terminating glaciers (both false positives and false negatives), although this can be improved by incorporating recent datasets such as Kochtitzky and Copland (Reference Kochtitzky and Copland2022). There have also been significant variations (typically retreat) of marine-terminating glaciers since the year 2000 (Kochtitzky and Copland, Reference Kochtitzky and Copland2022), but these are not reflected in the RGI. Improving the accuracy and consistency of RGI outlines across the globe for fixed dates (i.e., 2000, and more recently) in future versions should therefore be a priority, although it will take a massive collective effort to achieve a more accurate and consistent dataset. While GLIMS provides guidelines for submitting glacier polygons to the database, details about including and subdividing glacier geometries could help to standardize and improve these inventories.

Figure 2. Examples of inconsistencies in RGI v6.0. (a) Two glaciers with one RGI ID (RGI60-03.02489) with Landsat 8 imagery from 15 August 2019 on Devon Island, Canada. (b) Ice cap on Severnaya Zemlya, Russia without subdivisions with Landsat 8 imagery from 29 July 2019. (c) Ice cap with subdivisions in Franz Josef Land, Russia with Landsat 8 imagery from 20 July 2019. (d) Errors in Greenland showing incomplete glacier outlines with Landsat 8 imagery from 8 August 2018. (e) Locations of Figs 2a–d with land areas in gray.

Seperating ice sheet and periphery glacier mass loss is important to ensure consistency across studies. Glacier inventories for the ice sheets are generally more accurate, as glacier basins are typically larger and have simpler geometries, and there are relatively few ice sheet basins. Most recent discharge or frontal ablation estimates for ice sheets have relied on Mouginot and Rignot (Reference Mouginot and Rignot2019; Greenland) and Rignot and others (Reference Rignot2019; Antarctica). While Rastner and others (Reference Rastner2012) provided a first attempt to separate the hydrologic connectivity of Greenlandic periphery and ice sheet outlets, there is no similar inventory for Antarctica. For example, in Antarctica, some islands have glaciers that are surrounded by an ice shelf and feed into it, which are currently included in RGI v6.0. At the moment, there is no clear indication of which glaciers should be included or excluded in ice sheet and periphery glacier inventories, making studies inconsistent at best and at times inaccurate. Thus, a priority for the ice sheet and glacier communities in the coming years should be to clearly define how this seperaration should occur, and which glaciers are connected to the ice sheets and which are excluded, so that global studies are complete and consistent.

2.2 Flux gate placement and terminus area change

Ideally, flux gates should be positioned as close as possible to the calving front to minimize the corrections needed due to melt and sublimation processes down-glacier of the flux gate. Often, they are placed a minimum of a few hundred meters up-glacier from the calving face to ensure that velocity data are reliable and that the flux gate is above the most retreated position of the calving front during the considered period. When appropriate, ice sheet studies typically place the flux gate at the grounding line, which can be tens, if not hundreds, of kilometers up-glacier from the calving face (Gardner and others, Reference Gardner, Fahnestock and Scambos2019; Rignot and others, Reference Rignot2019). While some automated gate placement methods exist (Mankoff and others, Reference Mankoff2020), these methods introduce other uncertainties and are more reliant on existing glacier geometries/masks than manual procedures. Flux gate placements, except at the grounding line, and terminus area change quantifications both rely heavily on optical satellite imagery.

Dense records of optical imagery are important for robust gate placement (by ensuring that termini do not retreat behind the gates, even temporarily) and for measuring terminus area changes. Several satellite missions, with Landsat contributing the most, have collected imagery since the 1970s to inform flux gate creation and terminus area change measurements, but many data gaps exist in space and time. Data gaps exist at high latitudes because satellites (e.g., ASTER and Landsat) simply did not cover these areas, such as far northern Greenland and northern Ellesmere Island. Even though some of these sensors have been operating since the 1970s, many of them, particularly the older ones, did not collect data on every pass of the satellite, leaving numerous and large temporal and spatial gaps.

Gaps in the historical optical satellite record can be filled with synthetic aperture radar (SAR) data, from satellites such as Radarsat-1 and ALOS PALSAR, although this imagery is often of lower spatial resolution and is more difficult to interpret termini from than optical imagery, which is the case for ~2000 and ~2010 in northern Greenland and Ellesmere Island. Many polar locations have frequent cloud cover, leaving gaps of several years in the medium-resolution optical satellite image record, a real challenge for studies requiring higher temporal resolution for terminus area change measurements in the past. SAR, including Sentinel-1, may be useful in delineating glaciers in these areas (Rastner and others, Reference Rastner, Strozzi and Paul2017), but can also be more challenging to work with.

Recently, a new set of national-program optical satellites have been launched, comprising Landsat 8 (2013) and Landsat 9 (2021), and Sentinel 2a (2015) and Sentinel 2b (2017). Together, these provide high temporal repeat imaging and coverage to all latitudes where marine-terminating glaciers are found, and moreover are a part of an open data-access program by their agencies (Wulder and others, Reference Wulder2019; Zhu and others, Reference Zhu2019). These satellites are now collecting without spatial data gaps, and often with short intervals between acquisitions (<1 to 3 days, depending on latitude). With sometimes multiple images a day to choose from, choice of optical imagery is rarely a limitation in this part of frontal ablation calculations. Numerous commercial optical satellites have also been launched in the past two decades (e.g., WorldView, Planet, SkySat, SPOT 6 and 7), and in some cases abundant and accessible imagery is available from these sensors at no cost for researchers (e.g., through the European Space Agency's Third Party Missions Programme, and Planet Education and Research Program), at higher temporal and spatial resolutions than is possible from national-program satellites. We now face the challenge of picking the best imagery for the task and ensuring that datasets are consistent across satellite platforms.

To date, the only frontal ablation studies that have included terminus area changes have done so by using manual digitization of front positions and have, consequently, primarily relied on Landsat imagery (McNabb and others, Reference McNabb, Hock and Huss2015; Kochtitzky and others, Reference Kochtitzky2022). Manual delineation is partially necessary to ensure accuracy, for example when quantifying only the area that changed from ocean to land or vice versa. Using tools, such as GEEDiT (Lea, Reference Lea2018) to digitize glacier fronts can make the work more efficient. Recent work in automatically mapping glacier termini (e.g. Liu and others, Reference Liu, Enderlin, Marshall and Khalil2021; Goliber and others, Reference Goliber2022) represent a large dataset that, if incorporated properly, could greatly enhance the temporal resolution of frontal ablation observations and allow for quantification of seasonal variability.

Ice sheet grounding zones, mostly in Antarctica, are commonly mapped using either Differential Satellite Radar Interferometry (DInSAR; Rignot and others, Reference Rignot, Mouginot and Scheuchl2011) or laser altimetry (e.g., Li and others, Reference Li, Dawson, Chuter and Bamber2020). These methods map the line along which ice transitions from resting on the bed to floating, based on where tidal motion is seen. Grounding zones can be more than 2.5 km wide, such as that of Thwaites Glacier (Milillo and others, Reference Milillo2019), making identification of the location for the flux gate challenging. While marine-terminating glaciers without a grounding zone are more easily mapped with optical imagery, SAR imagery and laser altimetry are effective for these large glaciers, where the moderate resolution of SAR or the gaps between altimetry orbits are not problematic.

2.3 Velocity observations

Large-scale multi-temporal velocity mapping efforts, particularly the ITS_LIVE project (Gardner and others, Reference Gardner, Fahnestock and Scambos2019), make it possible, along with all the other required datasets, to estimate temporal variations in frontal ablation. However, there are data gaps and limitations in space and time, particularly in the early versions of this velocity data archive, mostly associated with the challenges of using optical imagery as described in section 2.2 (e.g., lack of far northern coverage). SAR datasets are also commonly used to map velocity for both glaciers (Friedl and others, Reference Friedl, Seehaus and Braun2021) and ice sheets (Rignot and others, Reference Rignot, Mouginot and Scheuchl2017; Joughin, Reference Joughin2022), and complement optical records. While velocity datasets have greatly improved in recent years, there are still many challenges.

One limitation with current velocity observations from high latitude regions is that they are determined from imagery collected at different times of the year: typically, in the spring-summer-fall for optical imagery due to the need for daylight (Gardner and others, Reference Gardner, Fahnestock and Scambos2019), and winter for SAR imagery due to the need for a frozen dry surface (Van Wychen and others, Reference Van Wychen2014; Strozzi and others, Reference Strozzi, Wiesmann, Schellenberger and Paul2022). Because the datasets can be temporally and spatially scarce, one must combine multiple datasets when estimating frontal ablation. Although systematic analyses are limited, marine-terminating glaciers can undergo significant seasonal velocity variations of >10%, with large differences between and within regions (Van Wychen and others, Reference Van Wychen2014, Reference Van Wychen2016; Strozzi and others, Reference Strozzi, Wiesmann, Schellenberger and Paul2022; Yang and others, Reference Yang2022).

Only a few studies have considered seasonal and annual variations in their frontal ablation or discharge estimates, such as in Greenland (King and others, Reference King2018; Mankoff and others, Reference Mankoff2020), Alaska (McNabb and others, Reference McNabb, Hock and Huss2015) and the Subantarctic (Osmanoǧlu and others, Reference Osmanoǧlu, Navarro, Hock, Braun and Corcuera2014). Better integration of optical and SAR observations, both spatially (regional) and temporally (winter and summer), will be important to improve frontal ablation estimates. Since frontal ablation rates are highest when ice velocities peak, accurate regional information as to how glacier velocity varies seasonally and annually is necessary to inform frontal ablation estimates and allow comparisons between different glaciers and regions.

Recent efforts to map glacier velocities globally (Gardner and others, Reference Gardner, Fahnestock and Scambos2019; Friedl and others, Reference Friedl, Seehaus and Braun2021) are a huge step forward, and with ice sheet specific datasets (Rignot and others, Reference Rignot, Mouginot and Scheuchl2017; Joughin, Reference Joughin2022) provide most of the velocity data needed for frontal ablation estimates, although some key gaps exist, mainly for mountain glaciers. Although recent efforts greatly improve velocity estimates from SAR imagery in the eastern Arctic for the 1990s to present (Strozzi and others, Reference Strozzi, Wiesmann, Schellenberger and Paul2022), we still need better temporal resolution and geographic/temporal coverage of velocity observations in many parts of Arctic Russia, northern Canada, and northernmost Greenland. While small glaciers make up a very small percentage of total frontal ablation, they often have the lowest spatial resolution and least accurate velocity data available, such as those in Jan Mayen, and may be good candidates for InSAR observations.

A major assumption in frontal ablation estimates is that depth-averaged velocity is a fixed fraction of surface velocity (Cuffey and Paterson, Reference Cuffey and Paterson2010). Since the depth-averaged velocity term multiplies with the frontal ablation (eq. 2), it can have a large impact of frontal ablation estimates. At present, studies outside the ice sheets typically assume that depth-averaged glacier velocity is less than 100% of the surface velocity, e.g., 90% (McNabb and others, Reference McNabb, Hock and Huss2015), 94% (Minowa and others, Reference Minowa, Schaefer, Sugiyama, Sakakibara and Skvarca2021), and 95% (Kochtitzky and others, Reference Kochtitzky2022). Ice sheet studies often assume that depth-averaged velocity is equal to the surface velocity, e.g., in Greenland (King and others, Reference King2018, Reference King2020; Mankoff and others, Reference Mankoff2020; Kochtitzky and others, Reference Kochtitzkyin review), and in Antarctica (Gardner and others, Reference Gardner2018). However, there are almost no in situ measurements available to confirm this assumption, and the ratio of surface velocity to depth-averaged velocity likely varies based on factors such as ice thickness, the relative importance of basal sliding vs internal deformation (Brinkerhoff and others, Reference Brinkerhoff, Aschwanden and Fahnestock2021), and ice temperature, all of which can vary temporally and spatially, particularly for mountain glaciers. The few studies that have looked at bed vs surface velocity have found that ice velocity at the bed can be between ~70% (Raymond, Reference Raymond1971; Willis and others, Reference Willis2003) and 99% (Seroussi and others, Reference Seroussi2011) that of the surface velocity. Thus, assumptions about depth-averaged velocity are almost certainly incorrect and significantly impact frontal ablation estimates, but the glaciology community currently lacks the data to define any better numbers to use instead. Future efforts to better measure depth-averaged velocity, particularly for the ice sheets, and to model it for each glacier, would improve frontal ablation estimates.

2.4 Glacier thickness

While the glaciology community has put considerable effort into collecting (MacGregor and others, Reference MacGregor2021) and compiling (GlaThiDa Consortium, 2019; Welty and others, Reference Welty2020) glacier thickness measurements, many glaciers still lack any observations. Kochtitzky and others (Reference Kochtitzky2022) found that the glaciers that together contributed 69% of Northern Hemisphere frontal ablation have at least one thickness observation along their flux gates, although this makes up only 18% of marine-terminating glaciers by count. Glacier and ice sheet models (Morlighem and others, Reference Morlighem2017, Reference Morlighem2020; Farinotti and others, Reference Farinotti2019; Millan and others, Reference Millan, Mouginot, Rabatel and Morlighem2022) are therefore critical to fill gaps, especially in glaciers lacking measurements. However, these models still struggle to estimate marine-terminating glacier thickness near termini, as few inversion studies account for frontal ablation when estimating ice thickness (e.g., Recinos and others, Reference Recinos, Maussion, Rothenpieler and Marzeion2019). For example, Kochtitzky and others (Reference Kochtitzky2022) found an average 135 m bias (modeled ice thickness was too high) between observations and model estimates from Millan and others (Reference Millan, Mouginot, Rabatel and Morlighem2022) along flux gates used in frontal ablation estimates; this is more than 100% of the average glacier thickness of ~120 m. More observations and improving ice thickness models, particularly near the calving face, are therefore important for improving frontal ablation estimates in the future.

Because glacier thickness measurements are typically derived from surface elevations that are available at much coarser temporal resolution than velocities, we need rates of elevation change to correct glacier thickness to match the time of the velocity observations. Globally complete surface-elevation-change-based estimates of glacier mass balance, at high resolution, are available outside the ice sheets (Hugonnet and others, Reference Hugonnet2021), and for the ice sheets (e.g. Smith and others, Reference Smith2020; Khan and others, Reference Khan2022), for the period 2000 to 2020. However, all these datasets report mass balance changes on annual to decadal time scales, and none report elevation changes on seasonal time scales that would match the temporal resolution of current velocity datasets. Repeat thickness observations of glaciers that produce most of the frontal ablation, are regionally important, and/or are changing rapidly would ensure accurate thickness estimates in these calculations. Recent and future campaigns, such as Operation IceBridge (MacGregor and others, Reference MacGregor2021), to collect more glacier thickness observations and water depth at the calving front will continue to improve this dataset. Glaciers without thickness measurements, but which have high frontal ablation rates should be a priority, such as those in the Russian Arctic (Kochtitzky and others, Reference Kochtitzky2022; Fig. 1).

Ice thickness data over the ice sheets is more comprehensive, although the spatial scale of the ice sheets allows them to benefit from relatively coarse (~1 km) ice thickness interpolations, a scale that would not be useful for most mountain glaciers. Significant community-wide efforts have managed to compile high-quality radar profile data for both the major ice sheets (e.g., Bamber and others, Reference Bamber2013; Fretwell and others, Reference Fretwell2013) as well as Patagonia (Millan and others, Reference Millan2019). Building on these compilations, an approach based on the conservation of mass combines ice thickness observations, surface velocity, surface elevation changes, and surface mass balance to provide the best mapping of ice thickness in between radar measurements (Huss and Farinotti, Reference Huss and Farinotti2014; Morlighem and others, Reference Morlighem2017, Reference Morlighem2020). We suggest community-based efforts to collect and compile radar ice thickness data for glaciers and ice sheets where information is currently lacking, such as for smaller outlet glaciers and regions with limited coverage such as the Russian Arctic.

2.5 Climatic mass balance down-glacier of a flux gate

To allow proper partitioning of total glacier-wide mass change into frontal ablation and climatic-basal mass balance, ice discharge through the flux gate needs to be corrected to account for the climatic mass balance that occurs down-glacier of the flux gate, a process which is impossible to measure on large scales with existing methods. Kochtitzky and others (Reference Kochtitzky2022) found that accounting for the climatic mass balance lowered discharge estimates by 20% and terminus mass change by 9%. Given that the location of the glacier terminus changes over time, this correction is needed for both the discharge component and retreat/advance component of frontal ablation. To approximate the climatic mass balance between the flux gate and calving face, we rely on glacier models (Hock and others, Reference Hock2019; Marzeion and others, Reference Marzeion2020; Rounce and others, Reference Rounce, Hock and Shean2020) or climate models (Noël and others, Reference Noël2018; van Wessem and others, Reference van Wessem2018). Glacier models are typically forced with air temperature and precipitation data from reanalysis products (e.g., ERA5; Hersbach and others, Reference Hersbach2020) and use temperature-index models to estimate surface melt. Since model outputs are only needed for a small portion of the glacier close to the terminus, results can be highly sensitive to uncertainties in the climate forcing and elevation-dependent model parameters and thus prone to errors, which hampers proper partitioning of the mass balance components down-glacier of the flux gate. Thus, modeled climatic balances must be carefully evaluated prior to deriving frontal ablation, but are critical to ensure accurate frontal ablation estimates.

2.6 Submarine, subaqueous frontal, and basal melt

Submarine melt is the sum of subaqueous frontal melting, which occurs along the submerged base of an approximately vertical calving front, and basal melt, which occurs along the underside of ice shelves and floating glacier tongues. In this context, only subaqueous frontal melt is a component of frontal ablation (Cogley and others, Reference Cogley2011). However, in much of the literature the terms submarine melt and subaqueous melt are used interchangeably and include melt processes at the ice-water interface along both the front and the base of marine-terminating glaciers and ice shelves (Truffer and Motyka, Reference Truffer and Motyka2016).

To date, all estimates of frontal ablation include basal melting (down-glacier of the flux gate) in their estimates, although they all claim it is negligible (Osmanoǧlu and others, Reference Osmanoǧlu, Braun, Hock and Navarro2013, Reference Osmanoǧlu, Navarro, Hock, Braun and Corcuera2014; Minowa and others, Reference Minowa, Schaefer, Sugiyama, Sakakibara and Skvarca2021; Kochtitzky and others, Reference Kochtitzky2022, Reference KochtitzkyIn Review). Estimates of Antarctic discharge at grounding lines typically include estimates of submarine melting as it accounts for over half the mass that passes through the flux gate (Rignot and others, Reference Rignot, Jacobs, Mouginot and Scheuchl2013).

No direct measurements of submarine melt exist, although multibeam sonar surveys have quantified submarine melt and calving (Sutherland and others, Reference Sutherland2019), and altimetry observations infer melt from ice shelf height changes (Adusumilli and others, Reference Adusumilli2018). Most field and satellite observations use a budget method, including residual thinning (Rignot and Jacobs, Reference Rignot and Jacobs2002; Pritchard and others, Reference Pritchard2012; Enderlin and Howat, Reference Enderlin and Howat2013); balance methods relying on oceanographic measurements of temperature, salinity, and water flux, or chemical tracers (Truffer and Motyka, Reference Truffer and Motyka2016; Huhn and others, Reference Huhn, Rhein, Kanzow, Schaffer and Sültenfuß2021); and observations and models of upwelling fresh water plumes (Jenkins, Reference Jenkins2011; Cowton and others, Reference Cowton, Todd and Benn2019; Jackson and others, Reference Jackson2022). Other work has focused on parametrizing subglacial melt (Cowton and others, Reference Cowton, Slater, Sole, Goldberg and Nienow2015; Jackson and others, Reference Jackson2022; Slater and Straneo, Reference Slater and Straneo2022). Parameterizations of plume-driven submarine melt rate use the product of total subglacial meltwater discharge at the calving front (sum of surface melting and subglacial frictional melting) and ocean thermal forcing (difference between ocean temperature and freezing point). These parameterizations may not provide the correct absolute values, but the relative changes in melt rate are well captured. These models are limited by assumptions about how meltwater enters fjords, meltwater quantity, and a lack of observationally based ocean temperature and bathymetry data (Slater and Straneo, Reference Slater and Straneo2022).

Submarine melt measured from ocean observations in front of two tidewater glaciers in Alaska accounted for ~50–65% of their frontal ablation (Motyka and others, Reference Motyka, Hunter, Echelmeyer and Connor2003, Reference Motyka, Dryer, Amundson, Truffer and Fahnestock2013; Bartholomaus and others, Reference Bartholomaus, Larsen and O'Neel2013; Jackson and others, Reference Jackson2022), while only 20% for a glacier in west Greenland (Xu and others, Reference Xu, Rignot, Fenty, Menemenlis and Flexas2013). Submarine melt under Antarctic ice shelves has been estimated to exceed ice sheet-wide calving flux by 30%, and locally by ~50% (Rignot and others, Reference Rignot, Jacobs, Mouginot and Scheuchl2013). The relative contribution of submarine melt is variable over time and space (Adusumilli and others, Reference Adusumilli2018; Fried and others, Reference Fried2019) but maximum rates occur where ocean thermal forcing is high and where ocean waters have access to grounding lines through deep troughs (Rignot and Jacobs, Reference Rignot and Jacobs2002; Motyka and others, Reference Motyka2011; Pritchard and others, Reference Pritchard2012).

Measurements or coupled ocean-ice sheet models that would enhance our understanding of the contribution and variability of submarine melt should include water column temperature and salinity stratification and upwelling, wind forcing, ice-proximal and subglacial bathymetry, subglacial discharge and melt plume behavior and changes in sea ice (Pritchard and others, Reference Pritchard2012; Bintanja and others, Reference Bintanja, van Oldenborgh, Drijfhout, Wouters and Katsman2013; Beckmann and others, Reference Beckmann2019; Cowton and others, Reference Cowton, Todd and Benn2019; Wagner and others, Reference Wagner2019; Slater and Straneo, Reference Slater and Straneo2022). Recent advances include an ice-sheet wide inventory of Greenland meltwater plumes in the context of fjord depth and discharge rates (Slater and others, Reference Slater2022). At regional and local scales, accurate ice thickness measurements are needed in addition to repeat high-resolution measurements of thinning of ice shelves and tidewater termini from satellite or airborne altimetry measurements (e.g., IceSat-2: Taubenberger and others, Reference Taubenberger, Felikson and Neumann2022; Operation IceBridge: MacGregor and others, Reference MacGregor2021).

2.7 Ice density

The density of snow and ice on a glacier can range from ~10 to over 917 kg m−3 (i.e., fresh snow to dense bottom ice; Cogley and others, Reference Cogley2011). At present, frontal ablation studies outside the ice sheets typically assume that ice density is 900 kg m−3 (Cuffey and Paterson, Reference Cuffey and Paterson2010; Kochtitzky and others, Reference Kochtitzky2022), while recent discharge studies on the Greenland Ice Sheet have typically assumed an ice density of 917 kg m−3 (King and others, Reference King2018, Reference King2020; Mankoff and others, Reference Mankoff2020). Work in Antarctica uses firn models for density (e.g., Stevens and others, Reference Stevens2020; Medley and others, Reference Medley, Neumann, Zwally, Smith and Stevens2022). In geodetic mass balance studies of valley glaciers, 850 kg m−3 is commonly used (Huss, Reference Huss2013). Since density is a direct multiplier on mass change, using a value of 900 kg m−3 instead of 917 kg m−3 results in a 1.9% reduction in the estimated frontal ablation. There is essentially no field data available to know what the density of an entire ice mass is, especially at low elevations. While ice cores can provide density estimates (e.g., Gow and others, Reference Gow1997), they are commonly extracted at high elevations for their climate record, and rarely taken at low elevations where density observations are needed for converting the ice flux into a mass flux. Crevasses, moulins and sub-, en-, and supra-glacial channels will alter the depth-density average of marine-terminating glaciers and thus directly impact the depth-averaged density. While current assumptions used in estimates of frontal ablation are certainly inaccurate, we lack field data to better inform this choice. Given the challenges of collecting observations close to the termini of glaciers, we need to develop models that can estimate this value from indirect or remote measurements, in frontal ablation calculations.

3. Conclusion

Frontal ablation is a critical component of global glacier mass loss, yet we still lack globally consistent estimates, primarily due to incomplete estimates from the periphery of the Antarctic Ice Sheet. In addition, estimates of the Antarctic Ice Sheet generally refer to grounding line ice discharge rather than frontal ablation at the calving front. Of course, improving underlying datasets globally, including glacier outlines, terminus changes, surface and depth-averaged velocity, glacier thickness, ice density, and basal-climatic balance, will reduce uncertainties in future work and make the estimates more accurate. Further field campaigns to collect thickness observations will improve past and future frontal ablation estimates. It is only practical to measure glacier velocities from space for inclusion in frontal ablation estimates and with the recent dramatic increase in the number of optical and other Earth observing satellites, velocity datasets will continue to improve. Furthering our understanding of glacier velocity variability will also refine modeling of ice thickness and increase the accuracy of frontal ablation estimates. Isolating the component of frontal ablation due to subaqueous frontal melting vs calving could enable models to account for the impact that changes in ocean temperatures have on marine-terminating glaciers and the relationship between subglacial discharge and frontal ablation. Furthermore, working together to improve methods of spatio-temporal estimation and error analysis, in ice thickness, velocity, and other variables, will have far reaching benefits beyond frontal ablation work.

Future work in calculating frontal ablation should focus on annual and seasonal estimates, especially in Greenland and Antarctica, where most frontal ablation occurs, but also in Svalbard and Arctic Russia, which dominates the frontal ablation of glaciers outside the ice sheets. In many glacier regions frontal ablation is both spatially heterogeneous and temporally variable. Glacier surges can strongly influence frontal ablation rates and may bias multi-year averages, which can be better understood with annual or seasonal estimates. However, it is also going to be challenging to work across a variety of spatio-temporal scales to estimate the frontal ablation of surge-type glaciers. While glacier velocity and terminus position observations are attainable on a weekly to monthly basis for many glaciers, other needed inputs, like thickness, are not as readily available at these time scales.

Frontal ablation and ice discharge studies to date have made different assumptions and have inconsistent mapping across regions. Future work would benefit from collaboration across these studies to increase consistency and close gaps. For example, the mountain glacier and ice sheet communities should mutually agree upon glacier inventories and which ice bodies belong as part of, or separate from, the ice sheets. More work on bulk ice density and deriving depth-averaged velocity from surface velocity, which is currently treated differently across glacier types, is equally critical, but will be a much harder problem to solve. Enhanced collaboration across glacier and ice sheet communities on methods, locations, and spatial scales can yield new insights into processes across the cryosphere. This can include better synthesis between existing networks such as the Global Terrestrial Network for Glaciers (GTN-G) and the Ice Sheet Model Intercomparison Project (ISMIP), or proposed initiatives such as the Greenland Ice Sheet-Ocean Observing System (GrIOOS: Straneo and others, Reference Straneo2019), together with community building and coordination through agencies such as the American Geophysical Union (AGU), International Association of Cryospheric Sciences (IACS) and national funding agencies (e.g. Catania and others, Reference Catania, Stearns, Moon, Enderlin and Jackson2020).

Acknowledgements

We thank Tavi Murray for establishing the International Glaciological Society Global Seminar Series talks from which this contribution developed, and we thank two anonymous reviewers and the Annals of Glaciology issue editors, especially Dr Michael Wood, for their comments and suggestions. We acknowledge funding from the University of Ottawa, Natural Sciences and Engineering Research Council of Canada, and ArcticNet Network of Centres of Excellence Canada, which helped to support this work. DR and RH were supported by NASA grants 80NSSC20K1296 and 80NSSC20K1595

References

Adusumilli, S and 5 others (2018) Variable basal melt rates of Antarctic Peninsula ice shelves, 1994–2016. Geophysical Research Letters 45(9), 40864095. doi: 10.1002/2017GL076652Google Scholar
Aschwanden, A and 7 others (2019) Contribution of the Greenland ice sheet to sea level over the next millennium. Science Advances 5(6), eaav9396. doi: 10.1126/sciadv.aav9396CrossRefGoogle ScholarPubMed
Bamber, JL and 10 others (2013) A new bed elevation dataset for Greenland. The Cryosphere 7(2), 499510. doi: 10.5194/tc-7-499-2013Google Scholar
Bartholomaus, TC, Larsen, CF and O'Neel, S (2013) Does calving matter? Evidence for significant submarine melt. Earth and Planetary Science Letters 380, 2130. doi: 10.1016/j.epsl.2013.08.014CrossRefGoogle Scholar
Beckmann, J and 5 others (2019) Modeling the response of Greenland outlet glaciers to global warming using a coupled flow line–plume model. The Cryosphere 13(9), 22812301. doi: 10.5194/tc-13-2281-2019CrossRefGoogle Scholar
Bintanja, R, van Oldenborgh, GJ, Drijfhout, SS, Wouters, B and Katsman, CA (2013) Important role for ocean warming and increased ice-shelf melt in Antarctic sea-ice expansion. Nature Geoscience 6(5), 376379. doi: 10.1038/ngeo1767Google Scholar
Bollen, K, Enderlin, E and Muhlheim, R (2022) Dynamic mass loss from Greenland's marine-terminating peripheral glaciers (1985–2018). Journal of Glaciology 69(273), 153163. doi: 10.1017/jog.2022.52.Google Scholar
Brinkerhoff, D, Aschwanden, A and Fahnestock, M (2021) Constraining subglacial processes from surface velocity observations using surrogate-based Bayesian inference. Journal of Glaciology 67(263), 385403. doi: 10.1017/jog.2020.112Google Scholar
Catania, GA, Stearns, LA, Moon, TA, Enderlin, EM and Jackson, RH (2020) Future evolution of Greenland's marine-terminating outlet glaciers. Journal of Geophysical Research: Earth Surface 125(2), e2018JF004873.Google Scholar
Cogley, JG and 10 others (2011) Glossary of Glacier Mass Balance and Related Terms. IHP-VII Tech. Doc. Hydrol. No 86.Google Scholar
Cowton, T, Slater, D, Sole, A, Goldberg, D and Nienow, P (2015) Modeling the impact of glacial runoff on fjord circulation and submarine melt rate using a new subgrid-scale parameterization for glacial plumes. Journal of Geophysical Research: Oceans 120(2), 796812. doi: 10.1002/2014JC010324Google Scholar
Cowton, TR, Todd, JA and Benn, DI (2019) Sensitivity of tidewater glaciers to submarine melting governed by plume locations. Geophysical Research Letters 46(20), 1121911227. doi: 10.1029/2019GL084215Google Scholar
Cuffey, KM and Paterson, WSB (2010) The Physics of Glaciers. Burlington, MA: Academic Press.Google Scholar
Depoorter, MA and 6 others (2013) Calving fluxes and basal melt rates of Antarctic ice shelves. Nature, 502, 8992. (03 October 2013). doi: 10.1038/nature12567Google Scholar
Dowdeswell, JA and Jeffries, MO (2017) Arctic Ice Shelves: An Introduction, 321. doi: 10.1007/978-94-024-1101-0_1Google Scholar
Enderlin, E and Howat, I (2013) Submarine melt rate estimates for floating termini of Greenland outlet glaciers (2000–2010). Journal of Glaciology 59(213), 6775. doi: doi:10.3189/2013JoG12J049CrossRefGoogle Scholar
Farinotti, D and 6 others (2019) A consensus estimate for the ice thickness distribution of all glaciers on Earth. Nature Geoscience 12(3), 168173. doi: 10.1038/s41561-019-0300-3Google Scholar
Flexas, MM, Thompson, AF, Schodlok, MP, Zhang, H and Speer, K (2022) Antarctic Peninsula warming triggers enhanced basal melt rates throughout West Antarctica. Science advances 8(31), eabj9134. doi: 10.1126/sciadv.abj9134CrossRefGoogle ScholarPubMed
Fretwell, P and 10 others (2013) Bedmap2: improved ice bed, surface and thickness datasets for Antarctica. The Cryosphere 7(1), 375393. doi: 10.5194/tc-7-375-2013Google Scholar
Fried, MJ and 6 others (2019) Distinct frontal ablation processes drive heterogeneous submarine terminus morphology. Geophysical Research Letters 46, 1208312091, doi: 10.1029/2019GL083980Google Scholar
Friedl, P, Seehaus, T and Braun, M (2021) Global time series and temporal mosaics of glacier surface velocities derived from Sentinel-1 data. Earth System Science Data 13(10), 46534675. doi: 10.5194/essd-13-4653-2021Google Scholar
Gardner, AS and 6 others (2018) Increased West Antarctic and unchanged East Antarctic ice discharge over the last 7 years. The Cryosphere 12(2), 521547. doi: 10.5194/tc-12-521-2018CrossRefGoogle Scholar
Gardner, AS, Fahnestock, MA and Scambos, TA (2019) ITS_LIVE regional glacier and ice sheet surface velocities. Data archived at National Snow and Ice Data Center. doi: 10.5067/6II6VW8LLWJ7Google Scholar
GlaThiDa Consortium (2019) Glacier Thickness Database 3.0.1. Zurich, Switzerland: World Glacier Monitoring Service. doi: 10.5904/wgms-glathida-2019-03Google Scholar
Goliber, S and 22 others (2022) TermPicks: a century of Greenland glacier terminus data for use in scientific and machine learning applications. The Cryosphere 16, 32153233. doi: 10.5194/tc-16-3215-2022Google Scholar
Gow, AJ and 6 others (1997) Physical and structural properties of the Greenland ice sheet project 2 ice core: a review. Journal of Geophysical Research: Oceans 102(C12), 2655926575. doi: 10.1029/97JC00165Google Scholar
Hersbach, H and 42 others (2020) The ERA5 global reanalysis. Quarterly Journal of the Royal Meteorological Society 146(730), 19992049. doi: 10.1002/qj.3803Google Scholar
Hock, R and 7 others (2019) GlacierMIP – A model intercomparison of global-scale glacier mass-balance models and projections. Journal of Glaciology 65(251), 453467. doi: 10.1017/jog.2019.22Google Scholar
Hugonnet, R and 10 others (2021) Accelerated global glacier mass loss in the early twenty-first century. Nature 592(April), 726731. doi: 10.1038/s41586-021-03436-zGoogle Scholar
Huhn, O, Rhein, M, Kanzow, T, Schaffer, J and Sültenfuß, J (2021) Submarine meltwater from Nioghalvfjerdsbræ (79 North Glacier), Northeast Greenland. Journal of Geophysical Research: Oceans 126, e2021JC017224. doi: 10.1029/2021JC017224Google Scholar
Huss, M (2013) Density assumptions for converting geodetic glacier volume change to mass change. The Cryosphere 7(3), 877887. doi: 10.5194/tc-7-877-2013CrossRefGoogle Scholar
Huss, M and Farinotti, D (2014) A high-resolution bedrock map for the Antarctic Peninsula. The Cryosphere 8(4), 12611273. doi: 10.5194/tc-8-1261-2014Google Scholar
Huss, M and Hock, R (2015) A new model for global glacier change and sea-level rise. Frontiers in Earth Science 3, 122. doi: 10.3389/feart.2015.00054Google Scholar
Ingels, J and 10 others (2021) Antarctic ecosystem responses following ice-shelf collapse and iceberg calving: science review and future research. Wiley Interdisciplinary Reviews: Climate Change 12(1), e682. doi: 10.1002/wcc.682Google Scholar
Jackson, RH and 6 others (2022) The relationship between submarine melt and subglacial discharge from observations at a tidewater glacier. Journal of Geophysical Research: Oceans 127(10), e2021JC018204. doi: 10.1029/2021JC018204CrossRefGoogle Scholar
Jenkins, A (2011) Convection-driven melting near the grounding lines of ice shelves and tidewater glaciers. Journal of Physical Oceanography 41(12), 22792294. doi: 10.1175/JPO-D-11-03.1Google Scholar
Joughin, I (2022) MEaSUREs Greenland Annual Ice Sheet Velocity Mosaics from SAR and Landsat, Version 4 [Data Set]. Boulder, Colorado USA. NASA National Snow and Ice Data Center Distributed Active Archive Center. Available at doi: 10.5067/RS8GFZ848ZU9(Date Accessed 10-14-2022).CrossRefGoogle Scholar
Khan, SA and 13 others (2022) Greenland mass trends from airborne and satellite altimetry during 2011–2020. Journal of Geophysical Research: Earth Surface 127, e2021JF006505. doi: 10.1029/2021JF006505CrossRefGoogle ScholarPubMed
King, MD and 6 others (2018) Seasonal to decadal variability in ice discharge from the Greenland ice sheet. Cryosphere 12(12), 38133825. doi: 10.5194/tc-12-3813-2018Google Scholar
King, MD and 8 others (2020) Dynamic ice loss from the Greenland ice sheet driven by sustained glacier retreat. Communications Earth and Environment 1(1), 17. doi: 10.1038/s43247-020-0001-2CrossRefGoogle Scholar
Kochtitzky, W and Copland, L (2022) Retreat of northern hemisphere marine-terminating glaciers, 2000–2020. Geophysical Research Letters 49(3), 110. doi: 10.1029/2021gl096501Google Scholar
Kochtitzky, W and 17 others (2022) The unquantified mass loss of Northern Hemisphere marine-terminating glaciers from 2000-2020. Nature Communications 13, 5835. doi: 10.1038/s41467-022-33231-xCrossRefGoogle ScholarPubMed
Kochtitzky, W and 8 others (In Review) Closing Greenland's mass balance: Frontal ablation of every Greenlandic glacier from 2000 to 2020. Geophysical Research Letters, Paper#2023GL104095.Google Scholar
Lea, JM (2018) The Google Earth Engine Digitisation Tool (GEEDiT) and the Margin change Quantification Tool (MaQiT) – simple tools for the rapid mapping and quantification of changing Earth surface margins. Earth Surface Dynamics 6, 551561. doi: 10.5194/esurf-6-551-2018Google Scholar
Lee, TK and Park, HJ (2021) Review of ice characteristics in ship-iceberg collisions. Journal of Ocean Engineering and Technology 35(5), 369381. doi: 10.26748/KSOE.2021.060CrossRefGoogle Scholar
Li, T, Dawson, GJ, Chuter, SJ and Bamber, JL (2020) Mapping the grounding zone of Larsen C ice shelf, Antarctica, from ICESat-2 laser altimetry. The Cryosphere 14(11), 36293643. doi: 10.5194/tc-14-3629-2020Google Scholar
Liu, J, Enderlin, E, Marshall, H and Khalil, A (2021) Automated detection of marine glacier calving fronts using the 2-D wavelet transform modulus maxima segmentation method. IEEE Transactions on Geoscience and Remote Sensing 59(11), 90479056. doi: 10.1109/TGRS.2021.3053235Google Scholar
MacGregor, JA and 45 others (2021) The scientific legacy of NASA's operation IceBridge. Reviews of Geophysics 59(2). doi: 10.1029/2020RG000712Google Scholar
Mankoff, KD and 5 others (2020) Greenland Ice sheet solid ice discharge from 1986 through March 2020. Earth System Science Data. 12(2), 13671383. doi: 10.5194/essd-12-1367-2020Google Scholar
Marzeion, B and 16 others (2020) Partitioning the uncertainty of ensemble projections of global glacier mass change. Earth's Future 8(7), 125. doi: 10.1029/2019EF001470Google Scholar
McNabb, RW, Hock, R and Huss, M (2015) Variations in Alaska tidewater glacier frontal ablation, 1985–2013. Journal of Geophysical Research: Earth Surface 120, 120136. doi: 10.1002/2014JF003276Google Scholar
Medley, B, Neumann, TA, Zwally, HJ, Smith, BE and Stevens, CM (2022) Simulations of firn processes over the Greenland and Antarctic ice sheets: 1980–2021. The Cryosphere 16(10), 39714011. doi: 10.5194/tc-16-3971-2022Google Scholar
Milillo, P and 6 others (2019) Heterogeneous retreat and ice melt of Thwaites Glacier, West Antarctica. Science Advances 5(1), eaau3433. doi: 10.1126/sciadv.aau3433Google Scholar
Millan, R and 10 others (2019) Ice thickness and bed elevation of the northern and southern Patagonian icefields. Geophysical Research Letters 46(12), 66266635. doi: 10.1029/2019GL082485Google Scholar
Millan, R, Mouginot, J, Rabatel, A and Morlighem, M (2022) Ice velocity and thickness of the world's glaciers. Nature Geoscience 15(2), 124129. doi: 10.1038/s41561-021-00885-zGoogle Scholar
Minowa, M, Schaefer, M, Sugiyama, S, Sakakibara, D and Skvarca, P (2021) Frontal ablation and mass loss of the Patagonian icefields. Earth and Planetary Science Letters 561, 116811. doi: 10.1016/j.epsl.2021.116811CrossRefGoogle Scholar
Moon, TA, Gardner, AS, Csatho, B, Parmuzin, I and Fahnestock, MA (2020) Rapid reconfiguration of the Greenland ice sheet coastal margin. Journal of Geophysical Research: Earth Surface 125(11), e2020JF005585. doi: 10.1029/2020JF005585Google Scholar
Morlighem, M and 31 others (2017) BedMachine v3: complete Bed topography and ocean bathymetry mapping of Greenland from multibeam echo sounding combined with mass conservation. Geophysical Research Letters 44(21), 11,05111,061. doi: 10.1002/2017GL074954Google Scholar
Morlighem, M and 36 others (2020) Deep glacial troughs and stabilizing ridges unveiled beneath the margins of the Antarctic ice sheet. Nature Geoscience 13(2), 132137. doi: 10.1038/s41561-019-0510-8Google Scholar
Motyka, RJ, Hunter, L, Echelmeyer, KA and Connor, C (2003) Submarine melting at the terminus of a temperate tidewater glacier, LeConte Glacier, Alaska, USA. Annals of Glaciology 36, 5765. doi: 10.3189/172756403781816374Google Scholar
Motyka, RJ and 5 others (2011) Submarine melting of the 1985 Jakobshavn Isbræ floating tongue and the triggering of the current retreat. Journal of Geophysical Research 116(F1). doi: 10.1029/2009jf001632Google Scholar
Motyka, RJ, Dryer, WP, Amundson, J, Truffer, M and Fahnestock, M (2013) Rapid submarine melting driven by subglacial discharge, LeConte Glacier, Alaska. Geophysical Research Letters 40(19), 51535158. doi: 10.1002/grl.51011CrossRefGoogle Scholar
Mouginot, J and 8 others (2019) Forty-six years of Greenland ice sheet mass balance from 1972 to 2018. Proceedings of the National Academy of Sciences of the USA 116(19), 92399244. doi: 10.1073/pnas.1904242116Google Scholar
Mouginot, J and Rignot, E (2019) Glacier catchments/basins for the Greenland Ice Sheet, Dryad, Dataset. doi: 10.7280/D1WT11Google Scholar
Noël, B and 10 others (2018) Modelling the climate and surface mass balance of polar ice sheets using RACMO2–Part 1: Greenland (1958–2016). The Cryosphere 12(3), 811831. doi: 10.5194/tc-12-811-2018Google Scholar
Obisesan, A and Sriramula, S (2018) Efficient response modelling for performance characterisation and risk assessment of ship-iceberg collisions. Applied Ocean Research 74, 127141. doi: 10.1016/j.apor.2018.03.003Google Scholar
Ochwat, N, Scambos, T, Fahnestock, M and Stammerjohn, S (2022) Characteristics, recent evolution, and ongoing retreat of Hunt Fjord ice shelf, northern Greenland. Journal of Glaciology 69(273), 5770. doi: 10.1017/jog.2022.44Google Scholar
Osmanoǧlu, B, Braun, M, Hock, R and Navarro, FJ (2013) Surface velocity and ice discharge of the ice cap on King George Island, Antarctica. Annals of Glaciology 54(63), 111119. doi: 10.3189/2013AoG63A517Google Scholar
Osmanoǧlu, B, Navarro, FJ, Hock, R, Braun, M and Corcuera, MI (2014) Surface velocity and mass balance of Livingston island ice cap, Antarctica. Cryosphere 8(5), 18071823. doi: 10.5194/tc-8-1807-2014CrossRefGoogle Scholar
Pfeffer, WT and 18 others (2014) The Randolph glacier inventory: a globally complete inventory of glaciers. Journal of Glaciology 60(221), 537552. doi: 10.3189/2014JoG13J176Google Scholar
Pritchard, H and 5 others (2012) Antarctic ice-sheet loss driven by basal melting of ice shelves. Nature 484(7395), 502505. doi: 10.1038/nature10968Google Scholar
Rastner, P and 5 others (2012) The first complete inventory of the local glaciers and ice caps on Greenland. The Cryosphere 6(6), 14831495. doi: 10.5194/tc-6-1483-2012Google Scholar
Rastner, P, Strozzi, T and Paul, F (2017) Fusion of multi-source satellite data and DEMs to create a new glacier inventory for Novaya Zemlya. Remote Sensing 9(11), 1122. doi: 10.3390/rs9111122CrossRefGoogle Scholar
Raymond, CF (1971) Flow in a transverse section of Athabasca Glacier, Alberta, Canada. Journal of Glaciology 10(58), 5584. doi: 10.3189/s0022143000012995Google Scholar
Recinos, B, Maussion, F, Rothenpieler, T and Marzeion, B (2019) Impact of frontal ablation on the ice thickness estimation of marine-terminating glaciers in Alaska. The Cryosphere 13(10), 26572672. doi: 10.5194/tc-13-2657-2019Google Scholar
RGI Consortium (2017) Randolph Glacier Inventory – A Dataset of Global Glacier Outlines: Version 6.0. doi: 10.7265/4m1f-gd79Google Scholar
Rignot, E and Jacobs, SS (2002) Rapid bottom melting widespread near Antarctic ice sheet grounding lines. Science 296(5575), 20202023. doi: 10.1126/science.1070942Google Scholar
Rignot, E, Mouginot, J and Scheuchl, B (2011) Antarctic grounding line mapping from differential satellite radar interferometry. Geophysical Research Letters 38(10). doi: 10.1029/2011GL047109Google Scholar
Rignot, E, Jacobs, S, Mouginot, J and Scheuchl, B (2013) Ice-shelf melting around Antarctica. Science 341(6143), 266270. doi: 10.1126/science.1235798Google Scholar
Rignot, E and 12 others (2016) Modeling of ocean-induced ice melt rates of five west Greenland glaciers over the past two decades. Geophysical Research Letters 43, 63746382. doi: 10.1002/2016GL068784Google Scholar
Rignot, E, Mouginot, J and Scheuchl, B (2017) MEaSUREs InSAR-Based Antarctica Ice Velocity Map, Version 2 [NSIDC-0484]. Boulder, Colorado USA. NASA National Snow and Ice Data Center Distributed Active Archive Center. doi: 10.5067/D7GK8F5J8M8R (Accessed 10-14-2022).CrossRefGoogle Scholar
Rignot, E and 5 others (2019) Four decades of Antarctic ice sheet mass balance from 1979–2017. Proceedings of the National Academy of Sciences 116(4), 10951103. doi: 10.1073/pnas.1812883116CrossRefGoogle ScholarPubMed
Rounce, DR, Hock, R and Shean, DE (2020) Glacier mass change in high mountain Asia through 2100 using the open-source Python Glacier Evolution Model (PyGEM). Frontiers in Earth Science 7, 120. doi: 10.3389/feart.2019.00331Google Scholar
Seroussi, H and 6 others (2011) Ice flux divergence anomalies on 79north Glacier, Greenland. Geophysical Research Letters 38(9), 15. doi: 10.1029/2011gl047338Google Scholar
Slater, DA and 7 others (2022) Characteristic depths, fluxes, and timescales for Greenland's tidewater glacier fjords from subglacial discharge-driven upwelling during summer. Geophysical Research Letters 49, e2021GL097081. doi: 10.1029/2021GL097081Google Scholar
Slater, DA and Straneo, F (2022) Submarine melting of glaciers in Greenland amplified by atmospheric warming. Nature Geoscience 15, 794799. doi: 10.1038/s41561-022-01035-9Google Scholar
Smith, B and 10 others (2020) Pervasive ice sheet mass loss reflects competing ocean and atmosphere processes. Science 368(6496), 12391242. doi: 10.1126/science.aaz5845CrossRefGoogle ScholarPubMed
Stevens, CM and 6 others (2020) The Community Firn Model (CFM) v1.0. Geoscientific Model Development 13(9), 43554377. doi: 10.5194/gmd-13-4355-2020Google Scholar
Straneo, F and 13 others (2019) The case for a sustained Greenland Ice Sheet-Ocean Observing System (GrIOOS). Frontiers in Marine Science 6, 138. doi: 10.3389/fmars.2019.00138Google Scholar
Strozzi, T, Wiesmann, A, Schellenberger, T and Paul, F (2022) Ice surface velocity in the Eastern Arctic from historical satellite SAR data. Earth System Science Data Discuss (February), 142. doi: 10.5194/essd-2022-44Google Scholar
Sutherland, DA and 8 others (2019) Direct observations of submarine melt and subsurface geometry at a tidewater glacier. Science 365(6451), 369374. doi: 10.1126/science.aax3528Google Scholar
Taubenberger, CJ, Felikson, D and Neumann, T (2022) Brief communication: preliminary ICESat-2 (Ice, Cloud and land Elevation Satellite-2) measurements of outlet glaciers reveal heterogeneous patterns of seasonal dynamic thickness change. The Cryosphere 16(4), 13411348.Google Scholar
Truffer, M and Motyka, RJ (2016) Where glaciers meet water: subaqueous melt and its relevance to glaciers in various settings. Reviews of Geophysics 54(1), 220239. doi: 10.1002/2015RG000494Google Scholar
van Wessem, JM and 10 others (2018) Modeling the climate and surface mass balance of polar ice sheets using RACMO2–Part 2: Antarctica (1979–2016). The Cryosphere 12(4), 14791498. doi: 10.5194/tc-12-1479-2018Google Scholar
Van Wychen, W and 6 others (2014) Glacier velocities and dynamic ice discharge from the Queen Elizabeth Islands, Nunavut, Canada. Geophysical Research Letters 41(2), 484490. doi: 10.1002/2013GL058558Google Scholar
Van Wychen, W and 6 others (2016) Characterizing interannual variability of glacier dynamics and dynamic discharge (1999-2015) for the ice masses of Ellesmere and Axel Heiberg Islands, Nunavut, Canada. Journal of Geophysical Research Earth Surface 121(1), 3963. doi: 10.1002/2015JF003708Google Scholar
Wagner, TJ and 6 others (2019) Large spatial variations in the flux balance along the front of a Greenland tidewater glacier. The Cryosphere 13, 911925. doi: 10.5194/tc-13-911-2019CrossRefGoogle Scholar
Welty, E and 10 others (2020) Worldwide version-controlled database of glacier thickness observations. Earth System Science Data 12(4), 30393055. doi: 10.5194/essd-12-3039-2020Google Scholar
Willis, I and 5 others (2003) Seasonal variations in ice deformation and basal motion across the tongue of Haut Glacier d'Arolla, Switzerland. Annals of Glaciology 36, 157167. doi: 10.3189/172756403781816455CrossRefGoogle Scholar
Wulder, MA and 10 others (2019) Current status of Landsat program, science, and applications. Remote Sensing of Environment 225, 127147. doi: 10.1016/j.rse.2019.02.015Google Scholar
Xu, Y, Rignot, E, Fenty, I, Menemenlis, D and Flexas, MM (2013) Subaqueous melting of Store Glacier, west Greenland from three-dimensional, high-resolution numerical modeling and ocean observations. Geophysical Research Letters 40(17), 46484653. doi: 10.1002/grl.50825Google Scholar
Yang, RR and 6 others (2022) Glacier surface speed variations on the Kenai Peninsula, Alaska, 2014–2019. Journal of Geophysical Research 127. doi: 10.1029/2022JF006599Google Scholar
Zhu, Z and 10 others (2019) Benefits of the free and open Landsat data policy. Remote Sensing of Environment 224, 382385. doi: 10.1016/j.rse.2019.02.016Google Scholar
Figure 0

Figure 1. (a) Frontal ablation of all marine-terminating glaciers in the Northern Hemisphere for 2010-2020. Each point shows the location of one glacier. Glaciers with frontal ablation rates <1 Gt a−1 are shown in blue, with larger contributions shown as yellow to red. The size of each circle corresponds to the total frontal ablation. (b) Frontal ablation intensity index along the coastline of each region. We define the frontal ablation intensity index as the sum of frontal ablation from all glaciers within 80 km (Greenland) and 50 km (everywhere else) of a given location. This highlights parts of the ocean that receive the most frontal ablation. Data from Kochtitzky and others (2022, In Review).

Figure 1

Figure 2. Examples of inconsistencies in RGI v6.0. (a) Two glaciers with one RGI ID (RGI60-03.02489) with Landsat 8 imagery from 15 August 2019 on Devon Island, Canada. (b) Ice cap on Severnaya Zemlya, Russia without subdivisions with Landsat 8 imagery from 29 July 2019. (c) Ice cap with subdivisions in Franz Josef Land, Russia with Landsat 8 imagery from 20 July 2019. (d) Errors in Greenland showing incomplete glacier outlines with Landsat 8 imagery from 8 August 2018. (e) Locations of Figs 2a–d with land areas in gray.