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Paths forward in radioglaciology

Published online by Cambridge University Press:  09 March 2023

Dustin M. Schroeder
Dustin M. Schroeder*
Affiliation:
Departments of Geophysics and of Electrical Engineering, Stanford University, Stanford, CA, USA
*
Author for correspondence: Dustin M. Schroeder, E-mail: dustin.m.schroeder@stanford.edu
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Abstract

Ice-penetrating radar sounding is a powerful geophysical tool for studying terrestrial and planetary ice with a rich glaciological heritage reaching back over half a century. Recent years have also seen rapid growth in both the radioglaciological community itself and in the scope and sophistication of its analysis of ice-penetrating radar data. This has been spurred by a combination of growing datasets and improvements in computational resources as well as advances in radar sounding instrumentation and platforms. Together, these developments are transforming the field and highlight exciting paths forward for future innovation and investigation.

Keywords

Glaciological instruments and methodsradio-echo soundingremote sensing
Type
Letter
Information
Annals of Glaciology , Volume 63 , Issue 87-89 , September 2022 , pp. 13 - 17
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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. Recent progress in data analysis

The collection and exploitation of radiometric and geometric information in ice-penetrating radar data has transformed our knowledge of the subsurface conditions and processes of ice in the polar regions and across the solar system. In 2019, the International Glaciological Society hosted a symposium and published an associated issue of the Annals of Glaciology focused on Five Decades of Radioglaciology (Schroeder and others, Reference Schroeder2020). The work presented in these venues included scientific investigations of ice-sheet and glacier bed conditions, radio-wave attenuation, englacial structure, interpretation and the growing of the field of planetary radioglaciology. Those advances and work undertaken since have transformed the analysis of radar sounding data from an activity primarily focused on measuring ice thickness, bed topography and radiostratigraphy to a rich source of geophysical information about a diverse range of glaciological conditions and processes. This transformation was made possible by exploiting the scattering, reflection, attenuation and reflectivity signatures in radar sounding data (Fig. 1). This paper presents selected recent progress in radar sounding data analysis since 2019 with a particular focus on work in the areas of near-surface processes, crystal orientation fabric, subglacial hydrology, basal thermal state and bed morphology and material.

Fig. 1. Advances in the analysis of ice-penetrating radar data have demonstrated the capacity to interpret signatures of radar scattering, reflection, attenuation and reflectivity to observe a growing range of near-surface, englacial and subglacial processes.

For much of its history, the analysis of radar sounding data has focused on relatively deep subsurface interfaces (e.g. internal layers or the ice/bed interface), however there has been a growing body of work looking at the surface and near surface (e.g. surface roughness, accumulation, firn properties, ice slabs, firn aquifers) (e.g. Case and Kingslake, Reference Case and Kingslake2022). For example, recent work has used radar sounding data to assess the impact of extreme melt seasons in Greenland on the production and growth of reduced-permeability ice layers which can affect the infiltration runoff of surface melt in subsequent seasons (Culberg and others, Reference Culberg, Schroeder and Chu2021). Additionally, the analysis of the radar signature of near-surface fractures also highlights their potential to enable investigations into the physical processes that underpin their formation and impact on ice-sheet evolution (Altenburg and others, Reference Altenburg, Culberg and Schroeder2022; McLeod and others, Reference McLeod2022).

An area of intense recent activity is the observation and investigation of ice-sheet crystal orientation fabric (COF). The COF of ice, which can affect and encode information about the viscosity of ice flow, can be measured using polarimetric radar sounding data (Jordan and others, Reference Jordan, Martín, Brisbourne, Schroeder and Smith2022). As a result, recent work has focused on the rapid observation of that signature using ground-based, stationary phase-sensitive radar sounding systems (Young and others, Reference Young2021; Ershadi and others, Reference Ershadi2022) as well as the development of approaches to constrain the birefringent COF signature in more abundant single-polarization radar sounding (Young and others, Reference Young2021). In addition to the effect of COF on contemporary ice rheology, this method has also been used to investigate flow around ice divides and ice domes as well as the history and stability of ice streams (Lilien and others, Reference Lilien, Rathmann, Hvidberg and Dahl–Jensen2021; Young and others, Reference Young2021; Ershadi and others, Reference Ershadi2022). Across these studies, creative and challenging approaches to analyzing data are shedding light on hard-to-observe conditions occurring at scales far below the intrinsic resolution of radar systems (at the scale of ice crystals) but which can affect and encode macroscopic ice-sheet behavior.

Subglacial water bodies (e.g. subglacial lakes and rivers) were some of the earliest, most common and most distinctive observables investigated in radar sounding data, but have also been the subject of significant recent work (e.g. Napoleoni and others, Reference Napoleoni2020; Rutishauser and others, Reference Rutishauser2022). For example, cross-system calibration of overlapping radar surveys collected by different radar systems enabled the analysis of subglacial water flow beneath and between the Thwaites and Pine Island Glaciers (Chu and others, Reference Chu2021). In a similar vein, geostatistical modeling of basal topography revealed by ice-penetrating data showed that subglacial drainage pathways are sensitive to topographic information below the typical interpolated resolution of bed topography datasets (MacKie and others, Reference MacKie, Schroeder, Zuo, Yin and Caers2021). In other work, ice-sheet models have been used to reproduce the along-flow transition from a distributed to channelized basal water system beneath Thwaites Glacier, which had been previously detected using radar bed echo specularity (Hager and others, Reference Hager, Hoffman, Price and Schroeder2021). Finally, analysis of ultra wide band (UWB) radar sounding data collected using a CReSIS (Center for the Remote Sensing of Ice Sheets) radar operated on an AWI (Alfred Wegner Institute) aircraft over Hiawatha Glacier, Greenland were used to analyze echoes from a groundwater system beneath the bed of the glacier and to determine that the bed above the groundwater table was either frozen or drained (Bessette and others, Reference Bessette, Schroeder, Jordan and MacGregor2021). Taken together, the studies highlighted here show how radioglaciology continues to improve understanding of subglacial water movement and how it impacts ice-sheet processes.

A related, but distinct, subsurface condition is the basal thermal state of the ice sheet. The strong temperature dependence of the englacial attenuation rate and strong reflectivity contrast between frozen, thawed and wet basal interfaces encode information about the thermal state of the ice sheet into the radiometric signal of radar sounding data. This has been exploited to identify an area of frozen bed in the upper catchment of the eastern tributary of Thwaites Glacier which may play a key role in the routing of ice flow from the Byrd Subglacial Basin into Pine Island Glacier (Chu and others, Reference Chu2021). If frozen patches like this (or others closer to the coast) thaw, they have the potential to reshape catchment boundaries and mass loss projections (Dawson and others, Reference Dawson, Schroeder, Chu, Mantelli and Seroussi2022). Radar observations of the ice-sheet thermal state can also constrain the stability of subglacial lake systems as well as poorly constrained ice-sheet boundary conditions like accumulation rate, melt, advection and geothermal flux (Wolovick and others, Reference Wolovick, Moore and Zhao2021; Zeising and Humbert, Reference Zeising and Humbert2021; Hills and others Reference Hills2022a, Reference Hills, Christianson, Jacobel, Conway and Pettersson2022b).

Recent work has also improved the characterization of the material and morphology of ice-sheet beds. Detailed analysis of wide-band and swath-imaging radar systems have revealed fine scale morphology of features on the bed which impacts basal sliding and ice flow (Franke and others, Reference Franke2021, Reference Franke2022; Hoffman and others, Reference Hoffman2022). As have dense ground-based surveys (Schlegel and others, Reference Schlegel2022). This finer-scale, sliding-governing, geologically diagnostic morphology falls (far) below the resolution of typical bed topography data products. Advances in the geostatistical characterization of bed topography have also enabled the representation of that kind of information at the catchment to ice-sheet scale (MacKie and others, Reference MacKie, Schroeder, Caers, Siegfried and Scheidt2020). Recent work has also highlighted the potential for geologic properties of the bed to be encoded in the reflectivity signature of the bed echoes (Tulaczyk and Foley, Reference Tulaczyk and Foley2020). This kind of higher-fidelity analysis of the geologic and geophysical sources of radar sounding echo strength signatures highlights the need for corresponding advances in both radioglaciological laboratory studies and electromagnetic modeling.

2. Future directions in technology

The 2019 IGS Symposium and Annals of Glaciology issue also addressed the data, systems and processing upon which such studies are based (Schroeder and others, Reference Schroeder2020). Crewed, fixed-wing aircraft (e.g. MacGregor and others, Reference MacGregor2021) have been the backbone of radar sounding surveys for the field's entire history, however recent advances in instrumentation, platforms and experiments are reshaping how radar sounding data are collected. This transformation is enabling a shift from collecting profiles in order to explore new areas with a single system to ecosystems of distinct and complementary sensors, platforms and observations (Fig. 2). These ecosystems can include, variously, satellite and UAV platforms, multi-static, multi-frequency, polarimetricand radiometric systems instruments, and repeat-pass, interferometric and in situ sensor network experiments.

Fig. 2. Developments in instruments and platforms are enabling radioglaciology to transition from a relatively data poor field typified by sparse profiles and point measurement to field richer spatial, temporal, geometric and signal coverage.

Given the transformative impact of surface-observing satellite remote-sensing data (e.g. velocity, imagery, altimetry) and the centrality of ice-penetrating radar as a geophysical tool in the field of glaciology, the idea of collecting radar sounding data from orbit is understandably appealing. As a result, a range of Earth-orbiting mission concepts building on the heritage of planetary radar sounders been put forward (Bruzzone and others, Reference Bruzzone, Bovolo, Carrer, Donini and Thakur2021; Gogineni and others, Reference Gogineni2021; Haynes and others, Reference Haynes2021; Heggy, Reference Heggy2021). Such missions stand to produce more uniform coverage of both bed topography and internal layers, which are currently observed by a patchwork of surveys and systems, and increase the potential for repeat observations (especially during winter). However, the terrestrial clutter environment can pose a significant obstacle, leading many mission concepts to include multi-element and multi-satellite arrays (Culberg and Schroeder, Reference Culberg and Schroeder2020; Bruzzone and others, Reference Bruzzone, Bovolo, Carrer, Donini and Thakur2021; Gogineni and others, Reference Gogineni2021; Haynes and others, Reference Haynes2021; Altenburg and others, Reference Altenburg, Culberg and Schroeder2022). Additionally, Earth-orbiting radar sounders face challenges from Earth's ionosphere, a more regulated radio emission environment, and dramatically higher temperature-dependent attenuation rates than planetary settings. In this scenario, ice shelves have among the most favorable link budgets for orbital radar sounder detection (Schroeder and others, Reference Schroeder2021).

Other promising, novel platforms for collecting radar sounding data are uncrewed aerial vehicles (UAVs) (e.g. Arnold and others, Reference Arnold2020). UAVs offer some of the same potential benefits as satellites (e.g. increased opportunity for repeat, regular and winter observations), but operate in a lower cost, range and altitude envelope. Their lower altitude and greater flexibility in managing energy budgets generally allows UAV-borne sounders to achieve more favorable link budgets and azimuth resolutions. Similarly, their operation below the ionosphere and from remote field sites offers greater flexibility in frequency and transmit power choices. Perhaps most uniquely, UAVs have the capacity to adaptively modify their flight plans to optimize specific scientific goals (Teisberg and others, Reference Teisberg, Schroeder, Broome, Lurie and Woo2022). This stands to be particularly impactful for time-series observations and topographic bed mapping with interpolation (e.g. kriging, mass-conservation, geostatistics or ML-based methods) which can exploit information in radar echo character or survey geometry to improve bed representation (e.g. Leong and Horgan, Reference Leong and Horgan2020; Rahnemoonfar and others, Reference Rahnemoonfar, Yari, Paden, Koenig and Ibikunle2021; Teisberg and others, Reference Teisberg, Schroeder and MacKie2021; Liu-Schiaffini and others, Reference Liu-Schiaffini, Ng, Grima and Young2022). For example, UAV flight-plans can be dynamically optimized to minimize the method-specific post-interpolation uncertainty in bed topography or modeled sea level contribution. As the availability, performanceand price of these platforms continue to evolve, UAVs stand to become increasingly attractive and impactful as sounding platforms.

As advances in platforms increase the abundance of radar sounding data, survey designs are increasingly able to expand from mapping the bed to observing the temporal evolution of the entire ice-sheet subsurface. In the relatively few areas where repeat radar sounding observations have been collected, they have produced new insights into subsurface conditions and processes across timescales from hours to decades. For example, repeat profiling has revealed seasonally evolving englacial water systems in mountain glaciers and multi-year refreezing water sills in Greenland (Church and others, Reference Church, Grab, Schmelzbach, Bauder and Maurer2020; Culberg and others, Reference Culberg, Schroeder and Steinbrügge2022). At shorter timescales, repeat-pass sounding can measure vertical displacements which can add a vertical component to the horizontal ice-surface velocities measurements routinely collected by satellites (Miller and others, Reference Miller, Ariho, Paden and Arnold2020; Castelletti and others, Reference Castelletti, Schroeder, Jordan and Young2021; Summers and others, Reference Summers, Schroeder and Siegfried2021). Repeat-pass radar sounding also has the potential to dramatically improve bed topography with swath imaging (e.g. Hoffman and others, Reference Hoffman2022). This survey-dependent data richness is particularly well suited to the adaptive and target-specific surveying capacity of UAVs and for feeding data-rich empirical approaches (e.g. physics-informed neural networks; Teisberg and others, Reference Teisberg, Schroeder and MacKie2021).

In addition to the advances in the platforms, acquisition and analysis described above, technical advances are occurring in the radar sounding instruments in and of themselves. This includes UWB systems and systems operating at higher center frequencies (Rodriguez-Morales and others, Reference Rodriguez-Morales2020, Yan and others Reference Yan2020a; Reference Yan2020b). Beyond the improved geometric resolution that these systems offer, their frequency diversity is deferentially sensitive to subsurface glaciological observables. For example, recent work has shown that multi-frequency, narrow-band sounding spanning three order of magnitude has the potential to disambiguate the potentially confounding contributions of basal roughness and material properties to the bed reflectivity signal (Broome and Schroeder, Reference Broome and Schroeder2022). Additionally, polarimetric systems have been developed which can constrain and correct the effect of birefringence on observed bed echo power (Dall, Reference Dall2020). Recent work has also shown that polarimetric systems are sensitive to subglacial water geometry and orientation (Scanlan and others, Reference Scanlan, Buhl and Blankenship2022). Finally, both active radar sounders and passive microwave radiometers are sensitive to ice-sheet temperatures (Broome and others, Reference Broome, Schroeder and Johnson2021; Johnson and others, Reference Johnson2021). Recent work has shown that wide-bandwidth UHF radar sounding data can been used in combination with radiometer data to correct near-surface effects in model-based radiometer temperature retrievals (Xu and others, Reference Xu2020). Further, other work has shown that radiometer data can be combined with VHF sounder data to exploit their complementary sensitivity to temperature to improve both temperature profile retrievals and to correct for attenuation in bed echo reflectivity (Broome and others, Reference Broome, Schroeder and Johnson2021). Taken as a whole, these advances in the information richness of data collected by new radar sounding instruments stand to enhance the range and quality of studies analyzing it.

Recent and ongoing developments in radar sounding systems are also enabling new acquisition and experimental designs including repeat surveys (e.g. Miller and others, Reference Miller, Ariho, Paden and Arnold2020) and ground-based deployments (e.g. Li and others, Reference Li, Wattal, Nunn, Paden and Yan2022). For example, recent work on developing a ground-based bi-static radar sounding system with direct-path synchronization has enabled the acquisition of data with large and variable offsets (up to several ice thicknesses and beyond) which is not achievable with commercial GPR systems (Bienert and others, Reference Bienert2022). These large offsets allow tomographic analyses that can yield improved constraints on englacial attenuation/temperature signals and the complex permittivity of the bed. The application of this type of system to study, for example, the configuration and evolution of englacial water systems stand to further enable the adaptation of variable-offset and array-based analysis approaches from exploration seismology to problems in glacier hydrology. Similarly, the successful and growing deployment of stationary, phase-sensitive radar systems are enabling the collection of time-series observations (with unprecedented temporal sampling) which go beyond measurements of vertical advection, basal melting and englacial water storage to include horizontal ice-flow and crevasse-formation processes (Summers and others, Reference Summers, Schroeder and Siegfried2021; McLeod and others, Reference McLeod2022). This shows the power of in situ, time-series and extended-deployment radar sounding experiments and paves the way for in situ radio sensor networks that can integrate the advantages of both the temporal sampling of the stationary phase-sensitive systems and the geometric sampling of multi-static systems. The realization and success of these kind of sensor networks will be greatly aided by the experience and innovation involved in creating robust in situ probes currently being deployed beneath and within ice sheets (Prior-Jones and others, Reference Prior-Jones2021). Similarly, the recent development and demonstration of passive radio-sounding systems for ranging and imaging (which exploit existing signals of opportunity rather than transmitting their own signal) have the potential to drive down the resource envelope required for both planetary and terrestrial radar sounding sensor networks (Peters and others, Reference Peters2021). Whether active or passive, muti- or mono-static, in situ radar sounding sensor networks stand to be an increasingly important tool for radioglaciolgy.

Acknowledgements

I acknowledge J.B. Wainwright and C.Y.N. Chen for their illustration work and A.L. Broome, R. Culberg, E. Dawson, E.J. MacKie, E. Mantelli, D.E. Ryan, T.O. Teisberg and T.J. Young for their discussions about the figures and thank editor R. Schlegel. This work was supported, in part, by NSF Grant 1745137.

References

Altenburg, M, Culberg, R and Schroeder, DM (2022) Empirical characterization of surface crevasse clutter in multi-frequency airborne ice-penetrating radar data. In IGARSS 2022 - 2022 IEEE International Geoscience and Remote Sensing Symposium, pp. 1684–1687.Google Scholar
Arnold, E and 6 others (2020) CReSIS airborne radars and platforms for ice and snow sounding. Annals of Glaciology 61(81), 5867. doi:10.1017/aog.2019.37CrossRefGoogle Scholar
Bessette, JT, Schroeder, DM, Jordan, TM and MacGregor, JA (2021) Radar-sounding characterization of the subglacial groundwater table beneath Hiawatha Glacier, Greenland. Geophysical Research Letters 48(10), e2020GL091432. doi:10.1029/2020gl091432Google Scholar
Bienert, NL and 7 others (2022) Post-processing synchronized bistatic radar for long offset glacier sounding. IEEE Transactions on Geoscience and Remote Sensing 60, 117. doi:10.1109/tgrs.2022.3147172Google Scholar
Broome, AL and Schroeder, DM (2022) A radiometrically precise multi-frequency ice-penetrating radar architecture. IEEE Transactions on Geoscience and Remote Sensing 60, 115. doi:10.1109/tgrs.2021.3099801Google Scholar
Broome, AL, Schroeder, DM and Johnson, JT (2021) Measuring englacial temperatures with a combined radar-radiometer. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 2947–2950.Google Scholar
Bruzzone, L, Bovolo, F, Carrer, L, Donini, E and Thakur, S (2021) STRATUS: a new mission concept for monitoring the subsurface of polar and arid regions. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 661–664.CrossRefGoogle Scholar
Case, E and Kingslake, J (2022) Phase-sensitive radar as a tool for measuring firn compaction. Journal of Glaciology 68(267), 139152.Google Scholar
Castelletti, D, Schroeder, DM, Jordan, TM and Young, D (2021) Permanent scatterers in repeat-pass airborne VHF radar sounder for layer-velocity estimation. IEEE Geoscience and Remote Sensing Letters 18(10), 17661770. doi:10.1109/lgrs.2020.3007514Google Scholar
Chu, W and 8 others (2021) Multisystem synthesis of radar sounding observations of the Amundsen Sea sector from the 2004–2005 field season. Journal of Geophysical Research. Earth surface 126(10), e2021JF006296. doi:10.1029/2021jf006296Google Scholar
Church, G, Grab, M, Schmelzbach, C, Bauder, A and Maurer, H (2020) Monitoring the seasonal changes of an englacial conduit network using repeated ground-penetrating radar measurements. The Cryosphere 14(10), 32693286. doi:10.5194/tc-14-3269-2020CrossRefGoogle Scholar
Culberg, R and Schroeder, DM (2020) Firn clutter constraints on the design and performance of orbital radar ice sounders. IEEE Transactions on Geoscience and Remote Sensing 58(9), 63446361. doi:10.1109/tgrs.2020.2976666Google Scholar
Culberg, R, Schroeder, DM and Chu, W (2021) Extreme melt season ice layers reduce firn permeability across Greenland. Nature Communications 12(1), 2336. doi:10.1038/s41467-021-22656-5CrossRefGoogle ScholarPubMed
Culberg, R, Schroeder, DM and Steinbrügge, G (2022) Double ridge formation over shallow water sills on Jupiter's moon Europa. Nature Communications 13, 2007. doi:10.1038/s41467-022-29458-3Google Scholar
Dall, J (2020) Estimation of crystal orientation fabric from airborne polarimetric ice sounding radar data. IGARSS 2020–2020 IEEE International Geoscience and Remote Sensing Symposium, pp. 2975–2978.Google Scholar
Dawson, EJ, Schroeder, DM, Chu, W, Mantelli, E and Seroussi, H (2022) Ice mass loss sensitivity to the Antarctic ice sheet basal thermal state. Nature Communications 13(1), 4957. doi:10.1038/s41467-022-32632-2Google Scholar
Ershadi, MR and 9 others (2022) Polarimetric radar reveals the spatial distribution of ice fabric at domes and divides in East Antarctica. The Cryosphere 16(5), 17191739. doi:10.5194/tc-16-1719-2022Google Scholar
Franke, S and 6 others (2021) Complex basal conditions and their influence on ice flow at the onset of the northeast Greenland ice stream. Journal of Geophysical Research: Earth Surface 126(3), e2020JF005689.Google Scholar
Franke, S and 9 others (2022) Holocene ice-stream shutdown and drainage basin reconfiguration in northeast Greenland. Nature Geoscience 15(12), 9951001.Google Scholar
Gogineni, S and 15 others (2021) UWB MIMO radars for sounding and imaging of ice on the earth and other celestial bodies. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 657–660.Google Scholar
Hager, AO, Hoffman, MJ, Price, SF and Schroeder, DM (2021) Persistent, extensive channelized drainage modeled beneath Thwaites Glacier, West Antarctica. The Cryosphere 16, 35753599. doi:10.5194/tc-2021-338CrossRefGoogle Scholar
Haynes, MS and 8 others (2021) Debris: distributed element beamformer radar for ice and subsurface sounding. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 651–654.Google Scholar
Heggy, E (2021) Exploring deserts response to climate change from the orbiting arid subsurface and ice sheet sounder (OASIS). 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 655–656.Google Scholar
Hills, BH and 10 others (2022a) Geophysics and thermodynamics at South Pole Lake indicate stability and a regionally thawed bed. Geophysical Research Letters 49(2), 110. doi: 10.1029/2021gl096218.Google Scholar
Hills, BH, Christianson, K, Jacobel, RW, Conway, H and Pettersson, R (2022b) Radar attenuation demonstrates advective cooling in the Siple Coast ice streams. Journal of Glaciology 1, 111. doi:10.1017/jog.2022.86Google Scholar
Hoffman, AO and 5 others (2022) The impact of basal roughness on Inland Thwaites Glacier sliding. Geophysical Research Letters 49(14), 096564. doi:10.1029/2021gl096564Google Scholar
Johnson, JT and 33 others (2021) Microwave radiometry at frequencies From 500 to 1400 MHz: an emerging technology for earth observations. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 14, 48944914. doi:10.1109/jstars.2021.3073286Google Scholar
Jordan, TM, Martín, C, Brisbourne, AM, Schroeder, DM and Smith, AM (2022) Radar characterization of ice crystal orientation fabric and anisotropic viscosity within an Antarctic ice stream. Journal of Geophysical Research: Earth Surface 127(6), 006673. doi:10.1029/2022jf006673Google Scholar
Leong, WJ and Horgan, HJ (2020) DeepBedMap: a deep neural network for resolving the bed topography of Antarctica. The Cryosphere 14(11), 36873705. doi:10.5194/tc-14-3687-2020Google Scholar
Li, L, Wattal, S, Nunn, J, Paden, J and Yan, JB (2022) Development of a MIMO VHF radar for the search of the oldest ice in Antarctica. IEEE Geoscience and Remote Sensing Letters 19, 15. doi:10.1109/lgrs.2022.3176287Google Scholar
Lilien, DA, Rathmann, NM, Hvidberg, CS and Dahl–Jensen, D (2021) Modeling ice-crystal fabric as a proxy for ice-stream stability. Journal of Geophysical Research: Earth Surface 126(9), 006306. doi:10.1029/2021jf006306Google Scholar
Liu-Schiaffini, M, Ng, G, Grima, C and Young, D (2022) Ice thickness from deep learning and conditional random fields: application to ice-penetrating radar data with radiometric validation. IEEE Transactions on Geoscience and Remote Sensing 60, 114. doi:10.1109/tgrs.2022.3214147Google Scholar
MacGregor, JA and 45 others (2021) The scientific legacy of NASA's operation iceBridge. Reviews of Geophysics 59(2), 165. doi: 10.1029/2020rg000712.Google Scholar
MacKie, EJ, Schroeder, DM, Caers, J, Siegfried, MR and Scheidt, C (2020) Antarctic topographic realizations and geostatistical modeling used to map subglacial lakes. Journal of Geophysical Research: Earth Surface 125(3), 122. doi: 10.1029/2019jf005420.Google Scholar
MacKie, EJ, Schroeder, DM, Zuo, C, Yin, Z and Caers, J (2021) Stochastic modeling of subglacial topography exposes uncertainty in water routing at Jakobshavn Glacier. Journal of Glaciology 67(261), 7583. doi:10.1017/jog.2020.84Google Scholar
McLeod, AA and 7 others (2022) Processing and detecting artifacts in multi-input multi-output phase-sensitive ice penetrating radar data. In IGARSS 2022–2022 IEEE International Geoscience and Remote Sensing Symposium, pp. 3786–3789.Google Scholar
Miller, B, Ariho, G, Paden, J and Arnold, E (2020) Multipass SAR processing for radar depth sounder clutter suppression, tomographic processing, and displacement measurements. IGARSS 2020–2020 IEEE International Geoscience and Remote Sensing Symposium, pp. 822–825.CrossRefGoogle Scholar
Napoleoni, F and 9 others (2020) Subglacial lakes and hydrology across the Ellsworth Subglacial Highlands, West Antarctica. The Cryosphere 14(12), 45074524.Google Scholar
Peters, ST and 6 others (2021) Glaciological monitoring using the sun as a radio source for echo detection. Geophysical Research Letters 48(14), 111. doi: 10.1029/2021gl092450.Google Scholar
Prior-Jones, MR and 12 others (2021) Cryoegg: development and field trials of a wireless subglacial probe for deep, fast-moving ice. Journal of Glaciology 67(264), 627640. doi:10.1017/jog.2021.16Google Scholar
Rahnemoonfar, M, Yari, M, Paden, J, Koenig, L and Ibikunle, O (2021) Deep multi-scale learning for automatic tracking of internal layers of ice in radar data. Journal of Glaciology 67(261), 3948. doi:10.1017/jog.2020.80Google Scholar
Rodriguez-Morales, F and 12 others (2020) A mobile, multichannel, UWB radar for potential ice core drill site identification in East Antarctica: development and first results. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 13, 48364847. doi:10.1109/jstars.2020.3016287Google Scholar
Rutishauser, A and 7 others (2022) Radar sounding survey over Devon Ice Cap indicates the potential for a diverse hypersaline subglacial hydrological environment. The Cryosphere 16(2), 379395. doi:10.5194/tc-16-379-2022Google Scholar
Scanlan, KM, Buhl, DP and Blankenship, DD (2022) Polarimetric airborne radar sounding as an approach to characterizing subglacial Rthlisberger channels. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 15, 44554467. doi:10.1109/jstars.2022.3174473Google Scholar
Schlegel, R and 6 others (2022) Radar derived subglacial properties and landforms beneath Rutford Ice Stream, West Antarctica. Journal of Geophysical Research: Earth Surface 127(1), e2021JF006349.Google Scholar
Schroeder, DM and 9 others (2020) Five decades of radioglaciology. Annals of Glaciology 61(81), 113. doi:10.1017/aog.2020.11Google Scholar
Schroeder, DM and 6 others (2021) Glaciological constraints on link budgets for orbital radar sounding of earth's ice sheets. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 647–650.Google Scholar
Summers, PT, Schroeder, DM and Siegfried, MR (2021) Constraining ice sheet basal sliding and horizontal velocity profiles using a stationary phase sensitive radar sounder. 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 5524–5527.Google Scholar
Teisberg, TO, Schroeder, DM, Broome, AL, Lurie, F and Woo, D (2022) Development of a UAV-borne pulsed ice-penetrating radar system. In IGARSS 2022–2022 IEEE International Geoscience and Remote Sensing Symposium, pp. 7405–7408.Google Scholar
Teisberg, TO, Schroeder, DM and MacKie, EJ (2021) A machine learning approach to mass-conserving ice thickness interpolation, 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, pp. 8664–8667.Google Scholar
Tulaczyk, SM and Foley, NT (2020) The role of electrical conductivity in radar wave reflection from glacier beds. The Cryosphere 14(12), 44954506. doi:10.5194/tc-14-4495-2020Google Scholar
Wolovick, MJ, Moore, JC and Zhao, L (2021) Joint inversion for surface accumulation rate and geothermal heat flow from ice-penetrating radar observations at Dome A, East Antarctica. Part II: ice sheet state and geophysical analysis. Journal of Geophysical Research: Earth Surface 126(5), 125. doi: 10.1029/2020jf005936.Google Scholar
Xu, H and 5 others (2020) A combined active and passive method for the remote sensing of ice sheet temperature profiles. Progress In Electromagnetics Research 167, 111126. doi:10.2528/pier20030601Google Scholar
Yan, JB and 11 others (2020a) Multiangle, frequency, and polarization radar measurement of ice sheets. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 13, 20702080. doi:10.1109/jstars.2020.2991682Google Scholar
Yan, JB and 9 others (2020b) UHF radar sounding of polar ice sheets. IEEE Geoscience and Remote Sensing Letters 17(7), 11731177. doi:10.1109/lgrs.2019.2942582Google Scholar
Young, TJ and 6 others (2021) Inferring ice fabric from birefringence loss in airborne radargrams: application to the eastern shear margin of Thwaites Glacier, West Antarctica. Journal of Geophysical Research: Earth Surface 126(5), e2020JF006023. doi:10.1029/2020jf006023Google Scholar
Zeising, O and Humbert, A (2021) Indication of high basal melting at the EastGRIP drill site on the northeast Greenland ice stream. The Cryosphere 15(7), 31193128.Google Scholar
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Fig. 1. Advances in the analysis of ice-penetrating radar data have demonstrated the capacity to interpret signatures of radar scattering, reflection, attenuation and reflectivity to observe a growing range of near-surface, englacial and subglacial processes.

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Fig. 2. Developments in instruments and platforms are enabling radioglaciology to transition from a relatively data poor field typified by sparse profiles and point measurement to field richer spatial, temporal, geometric and signal coverage.