Processes controlling the development of talus slopes in <scp>SW</scp> Spitsbergen: The role of deglaciation and periglacial conditions

Senderak, Krzysztof; Kondracka, Marta; Gądek, Bogdan

doi:10.1002/ldr.3716

Cited by 12 publications

(7 citation statements)

References 55 publications

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“…The thickness of the taluses is in line with the results obtained by [46,47] on the slopes on the eastern side of Fugleberget (20-25 m) and the western slope of Fannytoppen (30-35 m) and is a slightly thinner (8-20 m) than taluses of Revdalen [48]. The active nowadays talus slopes are thicker, which may be related to the different times of talus development initiation due to the progressive deglaciation in the Hornsund region [48]. The thickness and activity of the Fugleberget talus slopes increase eastwards in the direction of deglaciation in the Holocene 3500-2000 years BP [49].…”

Section: Geometry and Internal Structure Of The Talus Slopessupporting

confidence: 88%

“…By analyzing the transverse and longitudinal views of the profiles and applying variable setting parameters of the measuring device, repeated reflection horizons were obtained at maximum depths of 25-30 m in the area of maximum debris accumulation in the central section of the "active" cones "Talus II" and "Talus III", and at a depth of about 15 m on the "stabilized" "Talus IV". The thickness of the taluses is in line with the results obtained by [46,47] on the slopes on the eastern side of Fugleberget (20-25 m) and the western slope of Fannytoppen (30-35 m) and is a slightly thinner (8-20 m) than taluses of Revdalen [48]. The active nowadays talus slopes are thicker, which may be related to the different times of talus development initiation due to the progressive deglaciation in the Hornsund region [48].…”

Section: Geometry and Internal Structure Of The Talus Slopessupporting

confidence: 86%

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The Thickness of Talus Deposits in the Periglacial Area of SW Spitsbergen (Fugleberget Mountainside) in the Light of Slope Development Theories

Dolnicki

Grabiec

2022

Land

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Periglacial slopes are susceptible to recent climate change. The rate of morphogenetic processes depends on numerous factors. The most important of these is the warming of the air and ground, increased precipitation (extreme rainfall in particular), and the rate of snow cover decay. The dynamics of these processes may effectively modify contemporary slope development models. The paper shows the structure of selected talus slopes on a Fugleberget mountainside, based on field observations and radar (GPR) soundings. The results are then compared to classical slope models. The radar survey in April and May 2014 used a RAMAC CU II Malå GeoScience system equipped with a 30 MHz RTA antenna (Rough Terrain Antenna). Five GPR profiles of different lengths were obtained along the talus axes, transversally on Fugleberget and partly on the Hansbreen lateral moraine. According to the radar soundings, the maximum thickness of the debris deposits is 25–30 m. The thickness of the weathered material increases towards the talus cone’s terminal part, and debris deposits overlap marine sediments. The talus slopes’ morphometry shows that their current forms differ from standard slope models, which may be due to the significant acceleration of geomorphic processes resulting from climate change, including rapid warming in the last four decades.

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Section: Geometry and Internal Structure Of The Talus Slopessupporting

confidence: 88%

Section: Geometry and Internal Structure Of The Talus Slopessupporting

confidence: 86%

The Thickness of Talus Deposits in the Periglacial Area of SW Spitsbergen (Fugleberget Mountainside) in the Light of Slope Development Theories

Dolnicki

Grabiec

2022

Land

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“…Such situations were already found during previous ERT (Kasprzak, 2020) and seismic measurements (Majda nski et al, 2022). Deep water penetration is favoured by the coarsegrained material of the taluses deposited here (Senderak et al, 2021).…”

Section: Discussionmentioning

confidence: 95%

Spatial and temporal patterns of near‐surface ground temperature in the Arctic mountain catchment

Kasprzak

Szymanowski

2023

Land Degrad Dev

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We consider the case of a mountain catchment representative of southwest Spitsbergen to investigate the spatial and temporal variation in temperature of the near‐surface ground. We set up 20 thermistor strings distributed in different parts of the catchment, combine the measured data with land surface temperature (LST) retrieved from Landsat imagery, and verify the depth of ground thawing using electrical resistivity tomography. Under current climatic conditions, the thickness of the active layer (ALT) is at least 1.5 m, and in the lower parts of the catchment, between 3.5 and 4 m. The maximum ground surface temperature in the study area can be 27°C, and the temperature at a depth of 1.5 m, 5.4°C. We identified unfrozen ground (taliks) to a depth of 10–30 m in zones of water concentration at foot slopes and under river channels. The persistence of year‐round taliks at lake shores is possible. We verify the hypothesis that topographic parameters significantly determine the spatial variation of near‐surface ground temperature. For each level of temperature aggregation (from 6 h to 12 months data) and each examined the depth of the active layer, it is possible to identify environmental variables—related to energy conditions, heights, terrain relief, and ground surface moisture—significantly correlated with ground temperature, and consequently to specify multiple regression models. Topographic exposure and LST (used only in daily models), altitude, and various approximations of relative height are crucial in their construction. The ground temperature variance, unexplained in the regression analysis, prompts recognition of the critical role of factors not included in the modelling (groundwater, soil structure).

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“…GPR is one of the most useful tools in cryospheric studies (Farbrot et al 2005;Baelum 2007;Bernard et al 2014;Senderak et al 2021). Data processing was conducted using RadExplorer software.…”

Section: Data Processingmentioning

confidence: 99%

Polish Polar Research

Marciniak,

Osuch,

Wawrzyniak

et al. 2022

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This article presents the results of a geophysical survey from which detailed images of glacial and periglacial landforms and subsurface structures were obtained. Sediments and landforms on newly deglaciated terrain can be used to reconstruct the extent and character of glaciers in the past and add to the understanding of their response to climate and environmental changes. To derive spatial information from complex geomorphological terrain, joint interpretation of three non-intrusive geophysical methods were applied: Electrical Resistivity Tomography (ERT), Ground Penetrating Radar (GPR), and time-lapse Seismic Tomography. These were used to identify subsurface structures in the forefield of the retreating Hans Glacier in SW Spitsbergen, Svalbard. Three main zones were distinguished and described: outwash plain, terminal moraine from the last glacial maximum, and glacial forefield proximal to the glacier front. Geophysical profiles across these zones reveal information on glacio-fluvial sediment thickness and structure, ice thickness and structure, and bedrock topography. The freezing-thawing effect of the active layer has a strong and deep impact, as demonstrated by variations in P-wave velocity in the obtained outcomes. The results are discussed in the context of the current climate in Svalbard. This study provides a snapshot of ground parameters and the current state of the subsurface in southern Spitsbergen. The boundary between sediment-bedrock layers was estimated to be from 5 to 20 m in depth. It is the first such extensive description of periglacial structures in the forefield of the Hans Glacier, utilising the longest ERT profile (1500 m) in Svalbard together with deep GPR and precise seismic tomography.

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Processes controlling the development of talus slopes in SW Spitsbergen: The role of deglaciation and periglacial conditions

Cited by 12 publications

References 55 publications

The Thickness of Talus Deposits in the Periglacial Area of SW Spitsbergen (Fugleberget Mountainside) in the Light of Slope Development Theories

The Thickness of Talus Deposits in the Periglacial Area of SW Spitsbergen (Fugleberget Mountainside) in the Light of Slope Development Theories

Spatial and temporal patterns of near‐surface ground temperature in the Arctic mountain catchment

Polish Polar Research

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