Recent Acceleration of a Rock Glacier Complex, Ádjet, Norway, Documented by 62 Years of Remote Sensing Observations

Eriksen, Harald Øverli; Rouyet, Line; Lauknes, Tom Rune; Berthling, Ivar; Isaksen, Ketil; Hindberg, Heidi; Larsen, Yngvar; Corner, Geoffrey D.

doi:10.1029/2018gl077605

Cited by 74 publications

(81 citation statements)

References 40 publications

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“…Facing the importance of documenting the changes occurring in the transfer rate of frozen debris over mountain slopes, the Swiss permafrost observation network PERMOS [18] has included a kinematics tier in its monitoring strategy, in addition to the observation of permafrost temperature and active layer trends. This is, however, not yet the case in other mountain regions or in the Global Terrestrial Network for Permafrost GTN-P [85], despite an increasing number of publications dedicated to this specific emerging geomorphological response to the climate warming [3,14,17,86,87]. In addition, inventories of rock glaciers and monitoring of rock glacier velocities is not explicitly mentioned by the Global Climate Observing System (GCOS) of the World Meteorological Organization (WMO) as being an essential climate variable (ECV) associated parameter, despite the fact that monitoring rock glacier velocities at the regional scale provides information on the impact of climate change on mountain slope stability, and rock glacier monitoring builds up a unique validation dataset of climate models for mountain regions, where direct permafrost (thermal state) measurements are scarce.…”

Section: Discussionmentioning

confidence: 99%

“…Rock glaciers typically occur in the following three forms: lobate (width-to-length ratio ≥1), tongue-shaped (width-to-length ratio <1), or spatulate (also termed piedmont type, these are tongue-shaped with a broadened terminus); depending on topography, several rock glaciers can merge or separate in flow direction [12,13].Annual rates of motion of rock glaciers range from a few millimeters (i.e., the lower boundary of detection accuracy) to several meters per year, whereby the surface of a rock glacier typically moves faster than the base through lateral velocities decreasing with depth. In addition, motion rates vary within the annual cycle [14], from year to year, as well as at the decennial time scale (e.g., [15][16][17][18]). During the last decade, an increasing number of studies have monitored in situ creep behavior of active rock glaciers in the European Alps [3,[18][19][20].…”

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confidence: 99%

“…Annual rates of motion of rock glaciers range from a few millimeters (i.e., the lower boundary of detection accuracy) to several meters per year, whereby the surface of a rock glacier typically moves faster than the base through lateral velocities decreasing with depth. In addition, motion rates vary within the annual cycle [14], from year to year, as well as at the decennial time scale (e.g., [15][16][17][18]). During the last decade, an increasing number of studies have monitored in situ creep behavior of active rock glaciers in the European Alps [3,[18][19][20].…”

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confidence: 99%

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Monitoring Rock Glacier Kinematics with Satellite Synthetic Aperture Radar

et al. 2020

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Active rock glaciers represent the best visual expression of mountain permafrost that can be mapped and monitored directly using remotely sensed data. Active rock glaciers are bodies that consist of a perennially frozen ice/rock mixture and express a distinct flow-like morphology indicating downslope permafrost creep movement. Annual rates of motion have ranged from a few millimeters to several meters per year, varying within the annual cycle, from year to year, as well as at the decennial time scale. During the last decade, in situ observations in the European Alps have shown that active rock glaciers are responding almost synchronously to inter-annual and decennial changes in ground temperature, suggesting that the relative changes of their kinematics are a general indicator of the evolution of mountain permafrost conditions. Here, we used satellite radar interferometry (InSAR) to monitor the rate of motion of various active rock glaciers in the Swiss Alps, Qeqertarsuaq (Western Greenland), and the semiarid Andes of South America. Velocity time series computed with Sentinel-1 SAR images, regularly acquired since 2014, every six days over Europe and Greenland and every 12 days over the Andes, show annual fluctuations, with higher velocities at the end of the summer. A JERS-1 image pair of 1996 and stacks of very high-resolution SAR images from TerraSAR-X and Cosmo-SkyMed from 2008 to 2017 were analyzed using InSAR and offset tracking over the Western Swiss Alps in order to extend the main observation period of our study. A quantitative assessment of the accuracy of InSAR and offset tracking was performed by comparison with in situ methods. Our results for the three different study regions demonstrate that Sentinel-1 InSAR can complement worldwide in situ measurements of active rock glacier kinematics.

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Section: Discussionmentioning

confidence: 99%

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Monitoring Rock Glacier Kinematics with Satellite Synthetic Aperture Radar

et al. 2020

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“…Additionally, these type of Pyrenaic rock glaciers, located close to the 0 o C isotherm, are suitable for being very interesting natural 'sensors' for climatic change. Especially considering that the increase of velocity of rock glaciers in recent years have also been documented in the Alps (Bodin et al, 2018) and Northern Norway (Eriksen et al, 2018). Also, the fact that the multitemporal dataset used in this study is open access, easily available and will soon be covering all the Spanish mountain ranges, it can be widely used for assessing all the rock glaciers and understanding how they are responding to climate change in these past 5 years.…”

Section: Implications In Climatic Monitoringmentioning

confidence: 99%

PYRENAIC ROCK GLACIERS: AN AIRBORNE AND MULTITEMPORAL LiDAR MONITORING CASE STUDY IN THE BESIBERRI AREA

Bataller¹

2019

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The monitoring of rock glaciers is a current subject of interest because of its application as permafrost indicator and its sensitivity to climatic changes (especially temperature and precipitation). Alpine rock glaciers in the Pyrenees have been described by various authors, but to study them regionally has been a challenge since most of these studies are based on ground-based techniques. Two LiDAR campaigns (the first one completed in 2015 and the second one currently ongoing) performed by the Spanish Instituto Geográfico Nacional (IGN), up to now mainly used for land management purposes, present the perfect opportunity to combine both datasets and asses the movement of this periglacial features. The present work aims to show how by analysing two sets of open-source LiDAR data (acquired in 2011 and 2016) and calculating elevation difference, the mapping of these features can be enhanced. The results will show how some recently proposed potentially active rock glaciers are showing vertical displacement and some others are not. Additionally, the displacement results of the Besiberri NW rock glacier are compared versus the results obtained by previous studies (1993-2003) by Chueca and Julian (2005) showing an increase on the vertical displacement of the central area interpreted as possible destabilization due to ice core ablation. To conclude, the climate monitoring implications, the limitations of the technique and further work to improve these results together with future applications are also discussed.

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“…In this context, rock glaciers experiencing destabilization have recently become of interest. While active rock glaciers commonly present moderate interannual velocity variations that correlate with the ground temperature (Delaloye et al, 2008;Kellerer-Pirklbauer and Kaufmann, 2012; Evaluating the destabilization susceptibility of active rock glaciers 2009), destabilized rock glaciers are characterized by a significant acceleration that can bring the landform, or a part of it, to abnormally high velocities (Delaloye et al, 2013;Roer et al, 2008;Scotti et al, 2016;Lambiel, 2011;Eriksen et al, 2018). During this acceleration phase, morphological features typical of sliding processes, such as crevasses and scarps, appear and grow on the rock glacier surface.…”

Section: Introductionmentioning

confidence: 99%

Evaluating the destabilization susceptibility of active rock glaciers in the French Alps

et al. 2019

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Abstract. In this study, we propose a methodology to estimate the spatial distribution of destabilizing rock glaciers, with a focus on the French Alps. We mapped geomorphological features that can be typically found in cases of rock glacier destabilization (e.g. crevasses and scarps) using orthoimages taken from 2000 to 2013. A destabilization rating was assigned by taking into account the evolution of these mapped destabilization geomorphological features and by observing the surface deformation patterns of the rock glacier, also using the available orthoimages. This destabilization rating then served as input to model the occurrence of rock glacier destabilization in relation to terrain attributes and to spatially predict the susceptibility to destabilization at a regional scale. Significant evidence of destabilization could be observed in 46 rock glaciers, i.e. 10 % of the total active rock glaciers in the region. Based on our susceptibility model of destabilization occurrence, it was found that this phenomenon is more likely to occur in elevations around the 0 ∘C isotherm (2700–2900 m a.s.l.), on north-facing slopes, steep terrain (25 to 30∘) and flat to slightly convex topographies. Model performance was good (AUROC = 0.76), and the susceptibility map also performed well at reproducing observable patterns of destabilization. About 3 km2 of creeping permafrost, or 10 % of the surface occupied by active rock glaciers, had a high susceptibility to destabilization. Considering we observed that only half of these areas of creep are currently showing destabilization evidence, we suspect there is a high potential for future rock glacier destabilization within the French Alps.

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Recent Acceleration of a Rock Glacier Complex, Ádjet, Norway, Documented by 62 Years of Remote Sensing Observations

Cited by 74 publications

References 40 publications

Monitoring Rock Glacier Kinematics with Satellite Synthetic Aperture Radar

Monitoring Rock Glacier Kinematics with Satellite Synthetic Aperture Radar

PYRENAIC ROCK GLACIERS: AN AIRBORNE AND MULTITEMPORAL LiDAR MONITORING CASE STUDY IN THE BESIBERRI AREA

Evaluating the destabilization susceptibility of active rock glaciers in the French Alps

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