Characteristics of snow structure along Kongsvegen glacier (Svalbard)

Snow cover data in Arctic regions like Svalbard are scarce while interest in distribution, properties and development of Arctic snow is evident (in context of climate change, too). Contributing to that issue this work is based on comprehensive observations of physical snow parameters recorded in sno...

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Bibliographic Details
Main Author: Brakemeier, Maik
Format: Master Thesis
Language:English
Published: 2017
Subjects:
Svalbard
Arktis
Schneedecke
Schneehärte
Schneedichte
Kongsvegen Gletscher
Snow Micro Pen
Dichteparametrisierungen
Ramm Sonde
Schichtweise skalieren
Korntypen
arktisch meteorologische Bedingungen
Schneemodell
SnowPack
physikalische Schneeeigenschaften
Arctic
snow cover
snow hardness
snow density
Kongsvegen glacier
density parametrizations
Scaling methods
layer-wise depth scaling
grain types
Arctic meteorological conditions
snow model
firn aquifer
physical snow properties
Kongsvegen
Arktis*
Climate change
glacier
Online Access:https://resolver.obvsg.at/urn:nbn:at:at-ubi:1-10631
Description
Summary:Snow cover data in Arctic regions like Svalbard are scarce while interest in distribution, properties and development of Arctic snow is evident (in context of climate change, too). Contributing to that issue this work is based on comprehensive observations of physical snow parameters recorded in snow pits and using special instruments, respectively. The data were collected in spring 2011 and at several locations in a height transect along Kongsvegen glacier. Analysis mainly concerns description of gross profile characteristics, the identification and physical understanding of major structures and their spatial and temporal characteristics. Three of them are considered in detail in which context snow hardness data are particularly important. Analysis was supported by data from automatic weather stations operated at the sites of snow investigations. These data also served to drive a numerical snow model. Model output was compared to observations and effectively served development of a process-based interpretation and reconstruction of the history of the investigated key layers. Different depth scaling method were developed to make the snow profiles comparable because snow depth strongly depends on altitude. The layer-wise depth scaling method yielded significant improvements in correlation between neighbouring snow hardness profiles along the glacier and at local scale. Three layers characterized by clear maxima in snow hardness, high density and mostly rounded grain types could thus be traced along the major part of the glacier. Attributions were comparatively uncertain if not impossible in the lower section of the glacier due to the higher temperatures and associated melt influences. Snow profiles were significantly correlated across decameter distances. The evolution history of the selected layers was investigated using relevant model output data. The latter were overall successfully validated by comparison with measured key parameters like snowheight, surface temperature or end-winter vertical profiles. Some ...

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