Ice calving
Ice calving, also known as glacier calving or iceberg calving, is the breaking off of chunks of ice at the edge of a glacier.[1] It is a form of ice ablation or ice disruption and is normally caused by the glacier expanding. It is the sudden release and breaking away of a mass of ice from a glacier, iceberg, ice front, ice shelf, or crevasse. The ice that breaks away can be classified as an iceberg, but may also be a growler, bergy bit, or a crevasse wall breakaway.[2]
Calving of glaciers is often accompanied by a loud cracking or booming sound[3] before blocks of ice up to 60 metres (200 ft) high break loose and crash into the water. The entry of the ice into the water causes large, and often hazardous waves.[4] The waves formed in locations like Johns Hopkins Glacier can be so large that boats cannot approach closer than 3 kilometres (1.9 mi). These events have become major tourist attractions in locations such as Alaska.
Many glaciers terminate at oceans or freshwater lakes which results naturally[5] with the calving of large numbers of icebergs. Calving of Greenland's glaciers produce 12,000 to 15,000 icebergs each year alone.[6]
Calving of ice shelves is usually preceded by a rift.[7] These events are not often observed.
Etymologically, calving is cognatic with calving as in birthing a calf.[8]
Causes
It is useful to classify causes of calving into first, second, and third order processes.[9] First order processes are responsible for the overall rate of calving at the glacier scale. The first order cause of calving is longitudinal stretching, which controls the formation of crevasses. When crevasses penetrate the full thickness of the ice, calving will occur.[10] Longitudinal stretching is controlled by friction at the base and edges of the glacier, glacier geometry and water pressure at the bed. These factors, therefore, exert the primary control on calving rate.
Second and third order calving processes can be considered to be superimposed on the first order process above, and control the occurrence of individual calving events, rather than the overall rate. Melting at the waterline is an important second order calving process as it undercuts the subaerial ice, leading to collapse. Other second order processes include tidal and seismic events, buoyant forces and melt water wedging.
When calving occurs due to waterline melting, only the subaerial part of the glacier will calve, leaving a submerged 'foot'. Thus, a third order process is defined, whereby upward buoyant forces cause this ice foot to break off and emerge at the surface. This process is extremely dangerous, as it has been known to occur, without warning, up to 300m from the glacier terminus.[11]
Calving law
Though many factors that contribute to calving have been identified, a reliable predictive mathematical formula is still under development. Data is currently being assembled from ice shelves in Antarctica and Greenland to help establish a 'calving law'. Variables used in models include properties of the ice such as thickness, density, temperature, c-axis fabric, impurity loading, though 'ice front normal spreading stress', is likely the most important variable, however it is usually not measured.
There are currently several concepts upon which to base a predictive law. One theory states that the calving rate is primarily a function of the ratio of tensile stress to vertical compressive stress, i.e., the calving rate is a function of the ratio of the largest to smallest principle stress.[12] Another theory, based on preliminary research, shows that the calving rate increases as a power of the spreading rate near the calving front.
Major calving events
Filchner-Ronne Ice Shelf
In October, 1988, the A-38 iceberg broke away from the Filchner-Ronne Ice Shelf. It was about 150 km x 50 km, a mass of ice bigger than the area of Delaware. A second calving occurred in May 2000 and created an iceberg 167 km x 32 km.
Amery Ice Shelf
A major calving event occurred in 1962 to 1963. Currently, there is a section at the front of the shelf referred to as the 'loose tooth'. This section, about 30 km by 30 km is moving at about 12 meters per day and is expected to eventually calve away.[13]
Ward Hunt Ice Shelf
The largest observed calving of an ice island happened at Ward Hunt Ice Shelf. Sometime between August 1961 and April 1962 almost 600 km2 of ice broke away.[14]
Ayles Ice Shelf
In 2005, nearly the entire shelf calved from the northern edge of Ellesmere Island. Since 1900, about 90% of Ellesmere Island's ice shelves have calved and floated away. This event was the biggest of its kind for at least the past 25 years. A total of 87.1 km2 (33.6 sq mi) of ice was lost in this event. The largest piece was 66.4 km2 (25.6 sq mi) in area, (equivalent in area to approximately 11,000 football fields or slightly larger than the City of Manhattan.[15]
Larsen Ice Shelf
This large ice shelf, located in the Weddell Sea, extending along the east coast of Antarctic Peninsula, consists of three segments, two of which have calved. The Larsen B Ice Shelf calved and disintegrated in February 2002. Then in January 1995, the Larsen A Ice Shelf containing 3,250 km² of ice 220 m thick calved and disintegrated.
Jakobshavn Isbrae Glacier
Also known as the Jakobshavn Glacier or Sermeq Kujalleq, in an ongoing event, 35 billion tonnes of icebergs calve off and pass out of the fjord every year.
Glacier surfing
First conceived in 1995 by Ryan Casey while filming for IMAX, this sport involves a surfer being towed into range by a jet ski and waiting for a mass of ice to calve from a glacier.[16] Surfers can wait for several hours in the icy water for an event. When a glacier calves, the mass of ice can produce 8 metre waves. Rides of 300 metres lasting for one minute can be achieved.[17]
See also
References
- ↑ Essentials of Geology, 3rd edition, Stephen Marshak
- ↑ Glossary of Glacier Terms, Ellin Beltz, 2006. Retrieved July 2009.
- ↑ Glacier Bay, National Park Service. Retrieved July 2009.
- ↑ Glacier Calving photos. Retrieved July 2009.
- ↑ ARCTIC, Vol. 39, No. 1 (March 1986) P. 15-19, Ice Island Calvings and Ice Shelf Changes, Milne Ice Shelf and Ayles Ice Shelf, Ellesmere Island, N.W.T., Martin O. Jeffries, 1985, University of Calgary. Retrieved 18 July 2009.
- ↑ Oceans, Oxfam. Retrieved June 2009.
- ↑ Promotions/Public Relations (2006-12-08). "The loose tooth: rifting and calving of the Amery Ice Shelf - Australian Antarctic Division". Aad.gov.au. Retrieved 2010-07-30.
- ↑ "Calving | Define Calving at Dictionary.com". Dictionary.reference.com. Retrieved 2010-07-30.
- ↑ Benn, D., Warren, C. & Mottram, R. 2007. Calving processes and the dynamics of calving glaciers. Earth-Science Reviews, 82, 143-179.
- ↑ Nick, F., Van der Veen, C., Vieli, A. & Benn, D. 2010. A physically based calving model applied to marine outlet glaciers and implications for the glacier dynamics. Journal of Glaciology, 56, 781.
- ↑ How close should boats come to the fronts of Svalbard’s calving glaciers?
- ↑ "Modeling Iceberg Calving From Ice Shelves Using a Stress Based Calving Law: The". Adsabs.harvard.edu. Retrieved 2010-07-30.
- ↑ Business Support Group (2009-05-18). "Rifting and calving of the Amery Ice Shelf - Australian Antarctic Division". Aad.gov.au. Retrieved 2010-07-30.
- ↑ ARCTIC, Vol. 39, No. 1 (March 1986) P. 15-19, Ice Island Calvings and Ice Shelf Changes, Milne Ice Shelf and Ayles Ice Shelf, Ellesmere Island, N.W.T.
- ↑ "Ayles Ice Shelf - Dr. Luke Copland". Geomatics.uottawa.ca. Retrieved 2010-07-30.
- ↑
- ↑ Archived February 1, 2009 at the Wayback Machine
Further reading
- Holdsworth, G. 1971. Calving From Ward Hunt Ice Shelf, 1961-1962., Canadian Journal Of Earth Sciences 8:299-305.
- Jeffries, M. 1982. Ward Hunt Ice Shelf, Spring 1982. Arctic 35542-544.
- Jeffries, M.O., And Serson, H. 1983. Recent Changes At The Front Of Ward Nwt. Arctic 36:289-290. Hunt Ice Shelf, Ellesmere Island, Koenig, L.S., Greenaway, K.R., Dunbar, M., And Haitersley
- Smith, G. 1952. Arctic Ice Islands. Arctic 5:67-103.
- Lyons, J.B., And Ragle, R.H. 1962. Thermal History And Growth Of The Ward Hunt Ice Shelf. International Union Of Geodesy And Geophysics International Association Of Hydrological Sciences, Colloque D’obergurgl, 10–18 September 1962. 88-97.
- Rectic And Maykut, G.A., And Untersteiner, N. 1971. Some Results From A Time Of Geophysical Research Dependent Thermodynamic Model Of Sea Ice. Journal 761550-1575.
External links
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