Linkage of cave-ice changes to weather patterns inside and outside the cave Eisriesenwelt (Tennengebirge, Austria)

Schöner, Wolfgang; Weyss, Gernot; Mursch-Radlgruber, Erich

doi:10.5194/tc-5-603-2011

Cited by 18 publications

(13 citation statements)

References 8 publications

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“…An ice cave is a rare phenomenon. Among the best known are Eisriesenwelt ice cave, Austria (May et al, 2011;Obleitner and Spötl, 2011;Schöner et al, 2011); Dobšináice cave, Slovakia (Bella, 2006;Lalkovič, 1995); Scȃrisoara ice cave, Romania (Holmlund et al, 2005;Perşoiu et al, 2011); and Monlesi ice cave, Switzerland (Luetscher et al, 2007(Luetscher et al, , 2008. Eisriesenwelt ice cave is the largest in the world.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of formation and preservation of Ningwu ice cave, Shanxi, China

Yang

Shi

2015

The Cryosphere

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Abstract. Ice caves exist in locations where annual average air temperature is higher than 0 • C. An example is Ningwu ice cave, Shanxi Province, the largest ice cave in China. In order to quantitatively investigate the mechanism of formation and preservation of the ice cave, we use the finite-element method to simulate the heat transfer process at this ice cave. There are two major control factors. First, there is the seasonal asymmetric heat transfer. Heat is transferred into the ice cave from outside very inefficiently by conduction in spring, summer and fall. In winter, thermal convection occurs that transfers heat very efficiently out of the ice cave, thus cooling it down. Secondly, ice-water phase change provides a heat barrier for heat transfer into the cave in summer. The calculation also helps to evaluate effects of global warming, tourists, colored lights, climatic conditions, etc. for sustainable development of the ice cave as a tourism resource. In some other ice caves in China, managers have installed airtight doors at these ice caves' entrances with the intention of "protecting" these caves, but this in fact prevents cooling in winter and these cave ices will entirely melt within tens of years.

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Section: Introductionmentioning

confidence: 99%

Numerical simulation of formation and preservation of Ningwu ice cave, Shanxi, China

Yang

Shi

2015

The Cryosphere

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“…However, making a straightforward connection between atmospheric warming trends and conditions in the ice cave suffers from a great deal of complexity, connected to the surface mass and energy balance and, in particular, anthropogenic technical measures. Investigation of ice masses in karst caves pointed out that mass and energy balance in cave systems is more intricate (Schöner et al, 2011;Obleitner and Spötl, 2011) than for a glacier without englacial cavities as it would be the case when drilling an ice core. For instance, this potential warming influence is counteracted by ongoing efforts to actively control the air temperature in the ice tunnel and to protect the surface from ablation, which may contribute to keeping the ice frozen to bedrock.…”

Section: Cold-based Ice At Chli Titlismentioning

confidence: 99%

Investigating cold based summit glaciers through direct access to the glacier base: a case study constraining the maximum age of Chli Titlis glacier, Switzerland

et al. 2018

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Abstract. Cold glaciers at the highest locations of the European Alps have been investigated by drilling ice cores to retrieve their stratigraphic climate records. Findings like the Oetztal ice man have demonstrated that small ice bodies at summit locations of comparatively lower altitudes may also contain old ice if locally frozen to the underlying bedrock. In this case, constraining the maximum age of their lowermost ice part may help to identify past periods with minimum ice extent in the Alps. However, with recent warming and consequent glacier mass loss, these sites may not preserve their unique climate information for much longer. Here we utilized an existing ice cave at Chli Titlis (3030 m), central Switzerland, to perform a case study for investigating the maximum age of cold-based summit glaciers in the Alps. The cave offers direct access to the glacier stratigraphy without the logistical effort required in ice core drilling. In addition, a pioneering exploration had already demonstrated stagnant cold ice conditions at Chli Titlis, albeit more than 25 years ago. Our englacial temperature measurements and the analysis of the isotopic and physical properties of ice blocks sampled at three locations within the ice cave show that cold ice still exists fairly unchanged today. State-of-the-art micro-radiocarbon analysis constrains the maximum age of the ice at Chli Titlis to about 5000 years before present. By this means, the approach presented here will contribute to a future systematic investigation of cold-based summit glaciers, also in the Eastern Alps.

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“…a negative ice mass balance for a given year). Indeed, sublimation and melting are the two mechanisms for loss, and research indicates that there can be pronounced interannual variability of the ice mass balance within ice caves (Ohata et al, 1994;Schöner et al, 2011). At certain times of the year, often in late spring and summer, there can be quantities of water on top of the ice (Balch, 1900;Perşoiu et al, 2011b), which will subsequently refreeze later in the year.…”

Section: Williams and Mckaymentioning

confidence: 99%

“…If we restrict our attention to ice caves which have more than one entrance (and in our simplified model, the cave entrances are at the same elevation), it is possible that the interior airflow speeds would be significantly lower than the exterior winds if the entrances are occluded by rock fall. Research by Schöner et al (2011) of the Eisriesenwelt, an ice cave in the Austrian Alps with two open ends, has shown interior airflow speeds to be significantly less than surface winds (depending on the location in the cave, and the cave geometry). Accordingly in this present modeling study we have varied runs with interior airflow speeds ranging from 100% of the exterior wind speeds, down to 1% (explained later).…”

Section: Flow-through Modelmentioning

confidence: 99%

“…At certain times of the year, often in late spring and summer, there can be quantities of water on top of the ice (Balch, 1900;Perşoiu et al, 2011b), which will subsequently refreeze later in the year. The source of a liquid water layer on top of the ice can be percolating water from rain or snowmelt (Perşoiu et al, 2011b;Schöner et al, 2011) or it could be the result of melting of the ice surface within the cave itself (Ohata et al, 1994).…”

Section: Williams and Mckaymentioning

confidence: 99%

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Comparing flow-through and static ice cave models for Shoshone Ice Cave

Williams¹,

McKay²

2015

IJS

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Linkage of cave-ice changes to weather patterns inside and outside the cave Eisriesenwelt (Tennengebirge, Austria)

Cited by 18 publications

References 8 publications

Numerical simulation of formation and preservation of Ningwu ice cave, Shanxi, China

Numerical simulation of formation and preservation of Ningwu ice cave, Shanxi, China

Investigating cold based summit glaciers through direct access to the glacier base: a case study constraining the maximum age of Chli Titlis glacier, Switzerland

Comparing flow-through and static ice cave models for Shoshone Ice Cave

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