Semi-automated calibration method for modelling of mountain permafrost evolution in Switzerland

Marmy, A.; Rajczak, Jan; Delaloye, Reynald; Hilbich, Christin; Hoelzle, Martin; Kotlarski, Sven; Nötzli, Jeannette; Phillips, Marcia; Salzmann, Nadine; Staub, Benno; Hauck, Christian

doi:10.5194/tc-10-2693-2016

Cited by 42 publications

(47 citation statements)

References 91 publications

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“…The triggering mechanisms of slope instabilities can be diverse, and depend on subsurface material (e.g., unconsolidated 25 sediments versus bedrock), its characteristics (fractures and fissures, ice and water content, slope angle, geological layering), and changes of these properties with time (Hasler et al, 2012;Krautblatter et al, 2013;Ravanel et al, 2013;Phillips et al, 2016). Water infiltration into newly thawed parts of permafrost is often mentioned as a possible triggering mechanism (Hasler et al, 2012), but only few observational data are available.…”

Section: Permafrost Degradation and Slope Instabilitiesmentioning

confidence: 99%

“…ground-based GPS monitoring; Wirz et al, 2014Wirz et al, , 2016, and for the estimation of sediment transfer rates between rock wall and creeping permafrost bodies (Müller et al, 2014). These monitoring methods 20 are, however, restricted to rock glaciers, rockfalls and subsidence (e.g., Deline et al, 2015, Phillips et al, 2016. Remote sensing has so far not enabled thermal changes in permafrost to be assessed.…”

Section: Changes In Rock Glacier Flow Velocities and Volumementioning

confidence: 99%

“…These models should not be confused with permafrost distribution models 10 (Boeckli et al, 2012), which are mostly statistical and usually based on permafrost evidences such as rock glacier inventories or climatic variables such as potential incoming solar radiation or mean annual air temperature. Similar to land-surface schemes used for hemispheric permafrost modeling (e.g., Ekici et al, 2015;Chadburn et al, 2015;Peng et al, 2016), physically-based site-level models are used in combination with Regional Climate Models (RCM) for studies of long-term permafrost evolution (Farbrot et al, 2013;Scherler et al, 2013;Westermann et al, 2013;Marmy et al, 2016). Such models 15 are also used to explain the existence of specific permafrost phenomena in the European mountains (Scherler et al, 2014;Fiddes et al, 2015;Zhou et al, 2015;Haberkorn et al, 2016;Lüthi et al 2016,).…”

Section: Modellingmentioning

confidence: 99%

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The European mountain cryosphere: A review of past, current and future issues

Beniston

Farinotti

Stoffel

et al. 2017

Preprint

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Abstract. The mountain cryosphere is recognized to have important impacts on a range of environmental processes. This 30 paper reviews current knowledge on snow, glacier, and permafrost processes, as well as their past, current and future The Cryosphere Discuss., doi:10.5194/tc-2016Discuss., doi:10.5194/tc- -290, 2017 Manuscript under review for journal The Cryosphere Published: 9 January 2017 c Author(s) 2017. CC-BY 3.0 License. 2 evolution in mountain regions in mainland Europe. We provide a comprehensive assessment of the current state of cryosphere research in Europe and point to the different domains requiring further research to improve our understanding of climate-cryosphere interactions, cryosphere controls on physical and biological mountain systems, as well as related impacts.We highlight advances in the modeling of the cryosphere, and identify inherent uncertainties in our capability of projecting changes in the context of a warming global climate. 5

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Section: Permafrost Degradation and Slope Instabilitiesmentioning

confidence: 99%

Section: Changes In Rock Glacier Flow Velocities and Volumementioning

confidence: 99%

Section: Modellingmentioning

confidence: 99%

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The European mountain cryosphere: A review of past, current and future issues

Beniston

Farinotti

Stoffel

et al. 2017

Preprint

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“…Although parameter fitting techniques have been used to calibrate soil properties for ground thermal models in permafrost environments, the results have chiefly been applied to the prediction of future permafrost states (e.g. Harp et al, 2016;Marmy et al, 2016). Little work has been done that uses the resulting parameters to estimate observed changes to subsurface heat or liquid water content at the monitoring sites.…”

Section: Parameter Estimation From Physically-based Modelsmentioning

confidence: 99%

“…(Atchley et al, 2015;Nicolsky et al, 2007b). However, Marmy et al (2016) report that using the coefficient of determination (R 2 ) as an objective function improves calibration results near the freezing point. They also suggest that the total energy content of the ground could be incorporated into the objective function in future research.…”

Section: Parameter Estimation From Physically-based Modelsmentioning

confidence: 99%

Towards improved monitoring of changing permafrost by estimating soil characteristics from ground temperature time-series

Brown¹

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Knowledge of subsurface liquid water content is important in permafrost but continuous measurements are rarely collected at monitoring sites. Two parameter estimation methods are used to estimate soil thermal properties and freezing characteristic curves (SFCC) from temperature time series in order to calculate changes in ground liquid water content. Tests with synthetic data show that even with the addition of noise, estimated SFCCs are visually similar to their true shape. Overall, saturation water content and freezing temperature are easiest to estimate, whereas heat capacity and the van Genuchten n parameter, which controls the curvature of the SFCC, are more difficult. Different calibration periods may result in high variability for estimates of low sensitivity parameters. Weighting model error by ground energy content underestimates saturation water content, but provides good estimates of freezing point temperature. Applying these techniques at monitoring sites encounters challenges when model structure is not well chosen.iii ACKNOWLEDGEMENTS

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Water content and ground temperature variations in the active layer of a rock glacier in the Central Andes of San Juan, Argentina

López,

Baldis,

Liaudat

et al. 2024

Earth Surf Processes Landf

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This paper analyses the response of the active layer between 2018 and 2020 in a typical rock glacier in the Central Andes of Argentina, in terms of volumetric water content and ground temperature variations. The period 2018–2020 coincided with the warmest and driest years of the last fourth decades in the Central Andes, reflected also in the reduced cooling periods, and decreased extent and duration of snow coverage. We performed sedimentological studies and calculations of thermal properties, along with measurements of water content and soil temperature in the top meter of soil within the active layer. Afterward, using the Coupled Heat and Mass Transfer Model for the Soil–Plant–Atmosphere System (COUP) model software, a number of selected parameters were adjusted to get the best correlation between measured and simulated data, using air temperature and precipitation datasets from global reanalysis models as inputs. This numerical model allowed to interpret the physical processes driven by thermal and hydrological fluxes within the active layer of rock glaciers in the Central Andes. During the autumn, we observed upward migration of moisture controlled by cryosuction at the freezing front. Maximum soil water content and downward moisture migration take place in the end of winter and during the spring, starting with snowmelt and seasonal ice thawing. However, the upper part of the active layer remained much drier than saturation over the simulation period (2018–2019). From the hydrological balance analysis, it is deduced that the studied soil profile receives some inflow of groundwater during spring and summer. Results contribute to better understand the Andean cryo‐lithozone and may be a reference to study other rock glaciers using little and accessible equipment.

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Semi-automated calibration method for modelling of mountain permafrost evolution in Switzerland

Cited by 42 publications

References 91 publications

The European mountain cryosphere: A review of past, current and future issues

The European mountain cryosphere: A review of past, current and future issues

Towards improved monitoring of changing permafrost by estimating soil characteristics from ground temperature time-series

Water content and ground temperature variations in the active layer of a rock glacier in the Central Andes of San Juan, Argentina

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