Isotope hydrological studies of the perennial ice deposit of Saarhalle, Mammuthöhle, Dachstein Mts, Austria

A 5.28 m-long ice core was extracted from a major cave ice body in the Mammuthöhle cave system. The upper ~1.2 m of ice most likely originate from precipitation fallen before the 1960s (based on <8.5 TU). Characteristic fluctuations in electrical conductivity were observed in the cave ice profile...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Z. Kern, I. Fórizs, R. Pavuza, M. Molnár, B. Nagy
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2011
Subjects:
Environmental sciences
GE1-350
Geology
QE1-996.5
Dachstein
ice core
The Cryosphere
Online Access:https://doi.org/10.5194/tc-5-291-2011
https://doaj.org/article/8363cdcdffb643b6b263682925a8e1e9
Description
Summary:A 5.28 m-long ice core was extracted from a major cave ice body in the Mammuthöhle cave system. The upper ~1.2 m of ice most likely originate from precipitation fallen before the 1960s (based on <8.5 TU). Characteristic fluctuations in electrical conductivity were observed in the cave ice profile, which seem to mirror the fluctuation of karst and surface water in the water supply of the ice accumulation. The stable isotope composition does not support the hypothesis that ice layers with low conductivity are formed by freezing out of water vapour. Isotope fractionation effects during the freezing process are indicated by the enrichment of heavy stable isotopes ( 2 H, 18 O) in the ice compared to the potential sources (local precipitation, karst water) and by the characteristically low d -excess values. In addition, the cave ice water line shows a slope coefficient of 8.13. A two-component open-system model (i.e. a depleted component mixed with the freezing water) can adequately explain the measured isotopic compositions of the Saarhalle cave ice.

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