A general theory of rock glacier creep based on in‐situ and remote sensing observations

Cicoira, Alessandro; Marcer, Marco; Gärtner‐Roer, Isabelle; Bodin, Xavier; Arenson, Lukas U.; Vieli, Andreas

doi:10.1002/ppp.2090

Cited by 59 publications

(129 citation statements)

References 62 publications

Supporting

Mentioning

122

Contrasting

Order By: Relevance

“…ess.washington.edu/math, last access: 22 April 2021). The NENA production rate has been shown to be well applicable for the Alpine area (Claude et al, 2014). The 36 Cl surface exposure age was computed with a LIP in-housedeveloped MATLAB program based on the equations and constants given in Alfimov and Ivy-Ochs (2009, and references therein).…”

Section: Be and 36 CL Exposure Datingmentioning

confidence: 99%

Deciphering the evolution of the Bleis Marscha rock glacier (Val d'Err, eastern Switzerland) with cosmogenic nuclide exposure dating, aerial image correlation, and finite element modeling

et al. 2021

View full text Add to dashboard Cite

Abstract. We constrain the Holocene development of the active Bleis Marscha rock glacier (Err–Julier area, eastern Swiss Alps) with 15 cosmogenic nuclide exposure ages (10Be, 36Cl), horizontal surface creep rate quantification by correlating two orthophotos from 2003 and 2012, and finite element modeling. We used the latter to separate the control on surface movement exerted by topography and material properties. Bleis Marscha is a stack of three overriding lobes whose formation phases are separated by time gaps expressed morphologically as over-steepened terrain steps and kinematically as a sharp downslope decrease in surface movement. The three discrete formation phases appear to be correlated to major Holocene climate shifts: Early Holocene low-elevation lobes (∼8.9–8.0 ka, after the Younger Dryas), Middle Holocene lobe (∼5.2–4.8 ka, after the Middle Holocene warm period), and Late Holocene high-elevation lobes (active since ∼2.8 ka, intermittently coexisting with oscillating Bleis Marscha cirque glacierets). The formation phases appear to be controlled in the source area by the climate-sensitive accumulation of an ice-debris mixture in proportions susceptible to rock glacier creep. The ongoing cohesive movement of the older generations requires ice at a depth which is possibly as old as its Early–Middle Holocene debris mantle. Permafrost degradation is attenuated by “thermal filtering” of the coarse debris boulder mantle and implies that the dynamics of the Bleis Marscha lobes that once formed persisted over millennia are less sensitive to climate. The cosmogenic radionuclide inventories of boulders on a moving rock glacier ideally record time since deposition on the rock glacier root but are stochastically altered by boulder instabilities and erosional processes. This work contributes to deciphering the long-term development and the past to quasi-present climate sensitivity of rock glaciers.

show abstract

Section: Be and 36 CL Exposure Datingmentioning

confidence: 99%

Deciphering the evolution of the Bleis Marscha rock glacier (Val d'Err, eastern Switzerland) with cosmogenic nuclide exposure dating, aerial image correlation, and finite element modeling

et al. 2021

View full text Add to dashboard Cite

show abstract

“…(Delaloye et al, 2013;Wirz et al, 2014b). The method devised in this initial project (Buchli et al, 2012;Wirz et al, 2013) has proven very successful and was thus expanded to other locations and applications of monitoring (Kenner et al, 2018;Cicoira et al, 2021) as well as natural hazard mitigation (Kenner et al, 2020) in collaboration with partners of the Swiss Permafrost Monitoring Network (PERMOS), the Swiss cantonal and federal authorities (Randa Grossgufer, Wysse Schije, PERMOS GNSS sites) (Noetzli et al, 2019). The methodological approach and technology used is closely related to work that was pioneered at the Matterhorn Hörnligrat field site from 2008 (Talzi et al, 2007;Hasler et al, 2008) as well as the Jungfraujoch (Hasler et al, 2011).…”

Section: Field Sites and Project Historymentioning

confidence: 99%

“…The success of this in-situ kinematic monitoring methods and instrumentation developed in the context of the X-Sense project is further manifested by the fact that this technology has been chosen to also monitor sites with similar properties as the above mentioned in other regions of Switzerland. The Schafberg (Kenner et al, 2020), Muragl (Kääb et al, 1997;Kaeaeb et al, 1998), and Murtel-Corvatsch rock glaciers (Cicoira et al, 2019a(Cicoira et al, , 2021 are situated in the Upper Engadin valley and the Largario rock glacier is situated in the Blenio valley, TI (Scapozza et al, 2014).…”

Section: © Permasense Projectmentioning

confidence: 99%

“…In the year 2018 two more positions were instrumented on the fast moving tongue, with the goal of creating a spatially resolved network for the analysis of the spatial variability of rock glacier velocities at a daily scale (Cicoira et al, 2019b(Cicoira et al, , 2021.…”

Section: Rock Glaciersmentioning

confidence: 99%

“…In the same years, also vertical inclinometer profiles were measured manually, providing a unique dataset. Recent detailed process oriented studies are based on the dataset presented (Cicoira et al, 2019a(Cicoira et al, , 2021.…”

Section: Rock Glaciersmentioning

confidence: 99%

See 2 more Smart Citations

Kinematic observations of the mountain cryosphere using in-situ GNSS instruments

Beutel

Biri

Buchli

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. Permafrost warming is coinciding with accelerated mass movements, talking place especially in steep, mountainous topography. While this observation is backed up by evidence and analysis of both remote sensing as well as repeat terrestrial surveys undertaken since decades much knowledge is to be gained about the specific details, the variability and the processes governing these mass movements in the mountain cryosphere. This dataset collates data of continuously acquired kinematic observations obtained through in-situ Global Navigation Satellite Systems (GNSS) instruments that have been designed and implemented in a large-scale multi field-site monitoring campaign across the whole Swiss Alps. The landforms covered include rock glaciers, high-alpine steep bedrock bedrock as well as landslide sites, most of which are situated in permafrost areas. The dataset was acquired at 54 different stations situated at locations from 2304 to 4003 m a.s.l and comprises 209’948 daily positions derived through double-differential GNSS post-processing. Apart from these, the dataset contains down-sampled and cleaned time series of weather station and inclinometer data as well as the full set of GNSS observables in RINEX format. Furthermore the dataset is accompanied by tools for processing and data management in order to facilitate reuse, open alternate usage opportunities and support the life-long living data process with updates. To date this dataset has seen numerous use cases in research as well as natural-hazard mitigation and adaptation due to climate change.

show abstract

Pluri‐decadal evolution of rock glaciers surface velocity and its impact on sediment export rates towards high alpine torrents

Kummert

Bodin

Braillard

et al. 2021

Earth Surf Processes Landf

Self Cite

View full text Add to dashboard Cite

The acceleration of surface velocities observed over the last two decades on monitored rock glaciers worldwide is a widespread signal of the probable control of warming air temperatures on long-term permafrost creep. Yet, the actual consequences of this acceleration on sediment availability in high mountain catchments have never been properly estimated at the pluri-decadal scale. The present study

show abstract

A general theory of rock glacier creep based on in‐situ and remote sensing observations

Cited by 59 publications

References 62 publications

Deciphering the evolution of the Bleis Marscha rock glacier (Val d'Err, eastern Switzerland) with cosmogenic nuclide exposure dating, aerial image correlation, and finite element modeling

Deciphering the evolution of the Bleis Marscha rock glacier (Val d'Err, eastern Switzerland) with cosmogenic nuclide exposure dating, aerial image correlation, and finite element modeling

Kinematic observations of the mountain cryosphere using in-situ GNSS instruments

Pluri‐decadal evolution of rock glaciers surface velocity and its impact on sediment export rates towards high alpine torrents

Contact Info

Product

Resources

About