Ice cave
An ice cave is any type of natural cave (most commonly lava tubes or limestone caves) that contains significant amounts of perennial (year-round) ice. At least a portion of the cave must have a temperature below 0 °C (32 °F) all year round, and water must have traveled into the cave’s cold zone.
Terminology
This type of cave was first formally described by Englishman Edwin Swift Balch in 1900,[1] who suggested the French term glacieres should be used for them, even though the term ice cave was then, as now, commonly used to refer to caves simply containing year-round ice. Among speleologists, ice cave is the proper English term.[2]
A cavity formed within ice (as in a glacier) is properly called a glacier cave.[3]
Types
Ice caves occur as static ice caves, such as Durmitor Ice Cave, and dynamic or cyclical ice caves, such as Eisriesenwelt.[4]
Temperature mechanisms
In most of the world, bedrock caves are thermally insulated from the surface and so commonly assume a near-constant temperature approximating the annual average temperature at the surface. In some cold environments, such as that surrounding Mount Erebus, average surface (and thus cave) temperatures are below freezing, and with surface water available in summer, ice caves are possible and are sometimes overlain by fumarolic ice towers.[5] However, many ice caves exist in temperate climates, due to mechanisms that result in cave temperatures being colder than average surface temperatures where they formed.[6]
Cold traps: Certain cave configurations allow seasonal convection to import cold air from the surface in winter, but not warm air in summer. A typical example is an underground chamber located below a single entrance. In winter, cold dense air settles into the cave, displacing any warmer air which rises and exits the cave. In summer, the cold cave air remains in place as the relatively warm surface air is lighter and cannot enter. The cave will only exchange air when the surface air is cooler than the cave air. Some cold traps may ensnare surface snow and shade it from the summer sun’s rays, which may further contribute to the colder cave temperature.[6]
Permafrost: Even temperate environments can include pockets of bedrock that are below freezing year round, a condition called permafrost. For example, winter wind and an absence of snow cover may allow freezing deep enough to be protected from summer thaw, particularly in light-colored rock that does not readily absorb heat. Although the portion of a cave within this permafrost zone will be below freezing, permafrost generally does not allow water percolation, so ice formations are often limited to crystals from vapor, and deeper cave passages may be arid and completely ice-free. Ice caves in permafrost need not be cold-traps (although some are), provided they do not draught significantly in summer.
Evaporative cooling: In winter, dry surface air entering a moisture-saturated cave may have an additional cooling effect due to the latent heat of evaporation. This may create a zone within the cave that is cooler than the rest of the cave. Because many caves have seasonally-reversing draughts, the corresponding warming of the cave through condensation in summer may occur at a different location within the cave, but in any event a moisture-saturated cave environment is likely to experience much more evaporative cooling than condensative warming.
Types of ice
Different freezing mechanisms result in visually and structurally distinct types of perennial cave ice.
Ponded water: Surface water that collects and ponds in a cave before freezing will form a clear ice mass, and can be tens of metres thick and of great age. Large ice masses are plastic and can slowly flow in response to gravity or pressure from further accumulations. Sculpting from air flow and sublimation may reveal ancient accumulation bands within the ice.
Accumulated snow: Compressed under the weight of ongoing accumulations, snow sliding or falling into a cave entrance may eventually form ice that is coarsely crystalline, akin to glacier ice. True underground glaciers are rare.
Ice formations: Water that freezes before ponding may form icicles, ice-stalagmites, ice columns or frozen waterfalls.[6]
Airborne moisture (water vapor): Freezing vapor can form frost crystals, frost feathers and two-dimensional ice plates on the cave walls and ceiling.
Needle ice: Infiltrating water that freezes within the bedrock can sometimes be forced into the cave passage.
Intrusions: The weight of a surface glacier perched atop a cave entrance can force glacial ice a short distance into the cave. The only known examples of this phenomenon are the several 'ice plugs' at the back of Castleguard Cave in Alberta.
Examples
- Bandera Volcano Ice Cave (New Mexico, USA)[7]
- Bixby State Preserve (Iowa, USA)
- Booming Ice Chasm (Alberta, Canada)
- Bortig Pit Cave (Apuseni Mountains, Romania)[8]
- Canyon Creek Ice Cave (Alberta, Canada)
- Castleguard Cave (Alberta, Canada)
- Coudersport Ice Mine (Pennsylvania, USA)
- Decorah Ice Cave State Preserve (Iowa, USA)
- Demänovská Ice Cave (Slovakia)
- Dobšiná Ice Cave (Slovakia) UNESCO World Heritage site (2000)[9]
- Eisriesenwelt (Werfen, Austria)
- Grotta del Gelo (Sicily, Italy)
- Grotte Casteret (Aragon, Spanish Pyrenees)
- Ice Mountain (West Virginia, USA)
- Kungur Ice Cave (Perm Krai, Russia)
- Narusawa Ice Cave, (Mount Fuji, Japan)
- Niter Ice Cave (Idaho, USA)
- Sam's Point Preserve (New York, USA)
- Scărișoara Cave (Romania)[10]
- Schellenberg Ice Cave (Bavaria, Germany)
- Shawangunk Ridge (New York, USA)
- Speilsalen (Norway) collapsed in 2007
- Víðgelmir (West Iceland)
Further reading
- Macdonald, W.D. Mechanisms for Ice Development in Ice Caves of Western North America The Canadian Caver 25/1 and 25/2, 1993.
- Rachlewicz, G., Szczuciński, W. Seasonal, annual and decadal ice mass balance changes in Jaskinia Lodowa w Ciemniaku, the Tatra Mountains, Poland Theoretical and Applied Karstology, 17: 11-18, 2004. (documents ice mass loss in the Ciemniak Ice Cave, Poland).
References
- Balch, E.S. (1900). Glacieres or Freezing Caverns.
- Ford, Derek C.; Williams, P.W. (1989). Karst Geomorphology and Hydrology.
- "A Lexicon of Cave and Karst Terminology with Special Reference to Environmental Karst Hydrology" (PDF). Karst Waters Institute. 2002. Archived from the original (PDF) on 2012-12-17.
- Anonymous Eisriesenwelt: Scientific Background Archived 2016-03-04 at the Wayback Machine eisriesenwelt.at, undated, 7pp, retrieved January 2016.
- D. W. H. Walton (28 March 2013). Antarctica: Global Science from a Frozen Continent. Cambridge University Press. p. 61. ISBN 978-1-107-00392-7.
- Barck, C. (December 1913). "Caves". Mazama. Portland, OR: Mazamas. 4 (2): 61–69. Retrieved February 20, 2016.
- Features of the Bandera Crater flow, Including Aa Lava & Ice CavesIce Cave at Bandera Volcano Archived 2015-09-08 at the Wayback Machine Virtual Field Trip to the basalts of the Zuni-Bandera Malpais, New Mexico Institute of Mining & Technology, 2000, retrieved 17 January 2016.
- Bortig Pit Cave – The Underground Ice World, Travel Guide Romania website, June 2014, retrieved 17 January 2016.
- Dobšiná Ice Cave Slovak Caves Administration, undated, retrieved 17 January 2016.
- Scarisoara Ice Cave – the biggest underground glacier in Romania, Travel Guide Romania website, December 24, 2014, retrieved 17 January 2016.
External links
- The Virtual Cave: Ice Formations in Ice Caves goodearthgraphics.com
- Video of an ice cave in the Big Snowy Mountains of Montana YouTube video
- Rod Benson Big Ice Cave in the Pryor Mountains of Montana For Montana website, selfpublished, 2009, retrieved 17 January 2016.
- Eisriesenwelt Ice Cave photos Eisriesenwelt Austria, undated. retrieved 17 January 2016
- Kungur Ice Cave
- Durmitor Ice Cave Archived 2015-04-02 at the Wayback Machine
- Speleoglacio Ice Cave Research Group University of Milano, Italy
- Marco Plebani GROTTE DI GHIACCIO Marco Plebani website, June 2009, 3pp (in Italian), retrieved 17 January 2016.