Thermal characteristics of permafrost in the steep alpine rock walls of the Aiguille du Midi (Mont Blanc Massif, 3842 m a.s.l)

Magnin, Florence; Deline, Philip; Ravanel, Ludovic; Nötzli, Jeannette; Pogliotti, Paolo

doi:10.5194/tc-9-109-2015

Cited by 93 publications

(126 citation statements)

References 33 publications

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“…The data obtained are also essential for calibrating and validating numerical simulations (e.g. Haberkorn et al, 2015a, b;Magnin et al, 2015;Noetzli et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

Challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation

Luethi¹,

Phillips²

2016

Geogr. Helv.

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Abstract. Long-term borehole temperature monitoring in mountain permafrost environments is challenging under the hostile conditions reigning in alpine environments. On the basis of data measured in the SLF borehole network we show three situations where ground temperature data should be interpreted with caution. (i) Thermistors have the tendency to drift, particularly if exposed to moisture or mechanical strain. This induces apparent warming or cooling, which can be difficult to differentiate from real ground temperature changes. Recalibration of thermistor chains is impossible if they cannot be extracted as a result of borehole deformation in creeping permafrost terrain. A solution using zero-curtain-based detection of drift and correction of data is presented. This method is however limited to the active layer, due to the lack of a reference temperature at greater depth. (ii) In contrast to drift-induced apparent warming, actual warming may be induced by natural processes or by the effects of construction activity. (iii) Control data from neighbouring boreholes are sometimes used to fill data gaps and discern drift -however these data may only underline the strong spatial variability of ground temperatures rather than provide measurement redundancy. A selection of recently observed problems regarding borehole monitoring in a hostile measurement environment are discussed, and advantages and possible drawbacks of various solutions including measurement redundancy or alternate instrumentation are presented.

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“…The data obtained are also essential for calibrating and validating numerical simulations (e.g. Haberkorn et al, 2015a, b;Magnin et al, 2015;Noetzli et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

Challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation

Luethi¹,

Phillips²

2016

Geogr. Helv.

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“…), NW (3738 m) and NE (3745 m) faces of the Central Piton. Each of them was equipped with a chain of 15 thermistors (accuracy ± 0.1°C) measuring temperature between 30 cm and 10 m in depth every 3 h (Magnin et al, 2015b). The mean annual temperatures at 10 m indicated a warm permafrost in the S face (-1.5°C) and a cold one in the NW (-4.5°C, Fig.…”

Section: Boreholes In the Aiguille Du Midi Rock Wallsmentioning

confidence: 99%

“…Since 2005, significant efforts have been made to study both the thermal state of permafrost, which reflects past and current climates in high mountain areas, and the associated geomorphological dynamics. Instrumented boreholes, subsurface thermal measurements, and monitoring of morphodynamics are used to characterise the status of the permafrost in rock walls (Magnin et al, 2015b) or in surficial deposits (Bodin et al, 2009;Schoeneich et al, 2014) in the French Alps and its response to ongoing climate change. Most of this research is part of the French observation and permafrost monitoring network PermaFRANCE (Schoeneich et al, 2010).…”

mentioning

confidence: 99%

Mountain permafrost and associated geomorphological processes: recent changes in the French Alps

Bodin¹,

Schoeneich²,

Deline³

et al. 2015

rga

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“…Measuring rock wall temperatures (e.g. Gruber et al, 2004a;Haberkorn et al, 2015a;Hasler et al, 2011;Magnin et al, 2015;PERMOS, 2013) and in a further step modelling the spatial permafrost distribution in steep rock walls is therefore of great importance.…”

Section: Introductionmentioning

confidence: 99%

“…The highly variable spatial and temporal distribution of the snow cover strongly influences the ground thermal regime of steep rock faces (Haberkorn et al, 2015a, b;Magnin et al, 2015) due to the high surface albedo and low thermal conductivity of the snow cover, as well as energy consumption during snow melt (Bernhard et al, 1998;Keller and Gubler, 1993;Zhang, 2005). In gently inclined, blocky terrain, effective ground surface insulation from cold atmospheric conditions was observed and modelled for snow depths exceeding 0.6 to 0.8 m (Hanson and Hoelzle, 2004;Keller and Gubler, 1993;Luetschg et al, 2008).…”

mentioning

confidence: 99%

Distributed snow and rock temperature modelling in steep rock walls using Alpine3D

et al. 2017

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Abstract. In this study we modelled the influence of the spatially and temporally heterogeneous snow cover on the surface energy balance and thus on rock temperatures in two rugged, steep rock walls on the Gemsstock ridge in the central Swiss Alps. The heterogeneous snow depth distribution in the rock walls was introduced to the distributed, processbased energy balance model Alpine3D with a precipitation scaling method based on snow depth data measured by terrestrial laser scanning. The influence of the snow cover on rock temperatures was investigated by comparing a snowcovered model scenario (precipitation input provided by precipitation scaling) with a snow-free (zero precipitation input) one. Model uncertainties are discussed and evaluated at both the point and spatial scales against 22 near-surface rock temperature measurements and high-resolution snow depth data from winter terrestrial laser scans.In the rough rock walls, the heterogeneously distributed snow cover was moderately well reproduced by Alpine3D with mean absolute errors ranging between 0.31 and 0.81 m. However, snow cover duration was reproduced well and, consequently, near-surface rock temperatures were modelled convincingly. Uncertainties in rock temperature modelling were found to be around 1.6 • C. Errors in snow cover modelling and hence in rock temperature simulations are explained by inadequate snow settlement due to linear precipitation scaling, missing lateral heat fluxes in the rock, and by errors caused by interpolation of shortwave radiation, wind and air temperature into the rock walls.Mean annual near-surface rock temperature increases were both measured and modelled in the steep rock walls as a consequence of a thick, long-lasting snow cover. Rock temperatures were 1.3-2.5 • C higher in the shaded and sunny rock walls, while comparing snow-covered to snow-free simulations. This helps to assess the potential error made in ground temperature modelling when neglecting snow in steep bedrock.

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Thermal characteristics of permafrost in the steep alpine rock walls of the Aiguille du Midi (Mont Blanc Massif, 3842 m a.s.l)

Cited by 93 publications

References 33 publications

Challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation

Challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation

Mountain permafrost and associated geomorphological processes: recent changes in the French Alps

Distributed snow and rock temperature modelling in steep rock walls using Alpine3D

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