Sea ice

Sea ice arises as seawater freezes. Because ice is less dense than water, it floats on the ocean's surface (as does fresh water ice, which has an even lower density). Sea ice covers about 7% of the Earth's surface and about 12% of the world's oceans.[1][2][3] Much of the world's sea ice is enclosed within the polar ice packs in the Earth's polar regions: the Arctic ice pack of the Arctic Ocean and the Antarctic ice pack of the Southern Ocean. Polar packs undergo a significant yearly cycling in surface extent, a natural process upon which depends the Arctic ecology, including the ocean's ecosystems. Due to the action of winds, currents and temperature fluctuations, sea ice is very dynamic, leading to a wide variety of ice types and features. Sea ice may be contrasted with icebergs, which are chunks of ice shelves or glaciers that calve into the ocean. Depending on location, sea ice expanses may also incorporate icebergs.

Broken pieces of Arctic sea ice with a snow cover.

General features and dynamics

Hypothetical sea ice dynamics scenario showing some of the most common sea ice features.

Sea ice does not simply grow and melt. During its lifespan, it is very dynamic. Due to the combined action of winds, currents, water temperature, and air temperature fluctuations, sea ice expanses typically undergo a significant amount of deformation. Sea ice is classified according to whether or not it is able to drift, and according to its age.

Fast ice versus drift (or pack) ice

Sea ice can be classified according to whether or not it is attached (or frozen) to the shoreline (or between shoals or to grounded icebergs). If attached, it is called landfast ice, or more often, fast ice (from fastened). Alternatively, and unlike fast ice, drift ice occurs further offshore in very wide areas, and encompasses ice that is free to move with currents and winds. The physical boundary between fast ice and drift ice is the fast ice boundary. The drift ice zone may be further divided into a shear zone, a marginal ice zone and a central pack.[4] Drift ice consists of floes, individual pieces of sea ice 20 metres (66 ft) or more across. There are names for various floe sizes: small20 to 100 m (66 to 328 ft); medium100 to 500 m (330 to 1,640 ft); big500 to 2,000 m (1,600 to 6,600 ft); vast2 to 10 kilometres (1.2 to 6.2 mi); and giant – more than 10 km (6.2 mi).[5][6] The term pack ice is used either as a synonym to drift ice,[5] or to designate drift ice zone in which the floes are densely packed.[5][6][7] The overall sea ice cover is termed the ice canopy from the perspective of submarine navigation.[6][7]

Classification based on age

Another classification used by scientists to describe sea ice is based on age, that is, on its development stages. These stages are: new ice, nilas, young ice, first-year and old.[5][6][7]

New ice, nilas and young ice

Nilas in Baffin Bay

New ice is a general term used for recently frozen sea water that does not yet make up solid ice. It may consist of frazil ice (plates or spicules of ice suspended in water), slush (water saturated snow), or shuga (spongy white ice lumps a few centimeters across). Other terms, such as grease ice and pancake ice, are used for ice crystal accumulations under the action of wind and waves. When sea ice begins to form on a beach with a light swell, ice eggs up to the size of a football can be created.[8]

Nilas designates a sea ice crust up to 10 centimetres (3.9 in) in thickness. It bends without breaking around waves and swells. Nilas can be further subdivided into dark nilas – up to 5 cm (2.0 in) in thickness and very dark, and light nilas – over 5 cm (2.0 in) in thickness and lighter in color.

Young ice is a transition stage between nilas and first-year ice, and ranges in thickness from 10 cm (3.9 in) to 30 cm (12 in), Young ice can be further subdivided into grey ice10 cm (3.9 in) to 15 cm (5.9 in) in thickness, and grey-white ice15 cm (5.9 in) to 30 cm (12 in) in thickness. Young ice is not as flexible as nilas, but tends to break under wave action. In a compression regime, it will either raft (at the grey ice stage) or ridge (at the grey-white ice stage).

First-year sea ice

Distinction between 1st year sea ice (FY), 2nd year (SY), multiyear (MY) and old ice.

First-year sea ice is ice that is thicker than young ice but has no more than one year growth. In other words, it is ice that grows in the fall and winter (after it has gone through the new ice – nilas – young ice stages and grows further) but does not survive the spring and summer months (it melts away). The thickness of this ice typically ranges from 0.3 m (0.98 ft) to 2 m (6.6 ft).[5][6][7] First-year ice may be further divided into thin (30 cm (0.98 ft) to 70 cm (2.3 ft)), medium (70 cm (2.3 ft) to 120 cm (3.9 ft)) and thick (>120 cm (3.9 ft)).[6][7]

Old sea ice

Old sea ice is sea ice that has survived at least one melting season (i.e. one summer). For this reason, this ice is generally thicker than first-year sea ice. Old ice is commonly divided into two types: second-year ice, which has survived one melting season, and multiyear ice, which has survived more than one. (In some sources,[5] old ice is more than 2-years old.) Multi-year ice is much more common in the Arctic than it is in the Antarctic.[5][9] The reason for this is that sea ice in the south drifts into warmer waters where it melts. In the Arctic, much of the sea ice is land-locked.

Driving forces

While fast ice is relatively stable (because it is attached to the shoreline or the seabed), drift (or pack) ice undergoes relatively complex deformation processes that ultimately give rise to sea ice's typically wide variety of landscapes. Wind is thought to be the main driving force along with ocean currents.[1][5] The Coriolis force and sea ice surface tilt have also been invoked.[5] These driving forces induce a state of stress within the drift ice zone. An ice floe converging toward another and pushing against it will generate a state of compression at the boundary between both. The ice cover may also undergo a state of tension, resulting in divergence and fissure opening. If two floes drift sideways past each other while remaining in contact, this will create a state of shear.

Deformation

Sea ice deformation results from the interaction between ice floes, as they are driven against each other. The end result may be of three types of features:[6][7] 1) Rafted ice, when one piece is overriding another; 2) Pressure ridges, a line of broken ice forced downward (to make up the keel) and upward (to make the sail); and 3) Hummock, an hillock of broken ice that forms an uneven surface. A shear ridge is a pressure ridge that formed under shear – it tends to be more linear than a ridge induced only by compression.[6][7] A new ridge is a recent feature – it is sharp-crested, with its side sloping at an angle exceeding 40 degrees. In contrast, a weathered ridge is one with a rounded crest and with sides sloping at less than 40 degrees.[6][7] Stamukhi are yet another type of pile-up but these are grounded and are therefore relatively stationary. They result from the interaction between fast ice and the drifting pack ice.

Level ice is sea ice that has not been affected by deformation, and is therefore relatively flat.[6][7]

Leads and polynyas

Leads and polynyas are areas of open water that occur within sea ice expanses even though air temperatures are below freezing, and provide a direct interaction between the ocean and the atmosphere, which is important for the wildlife. Leads are narrow and linear – they vary in width from meter to km scale. During the winter, the water in leads quickly freezes up. They are also used for navigation purposes – even when refrozen, the ice in leads is thinner, allowing icebreakers access to an easier sail path, and submarines to surface more easily. Polynyas are more uniform in size than leads and are also larger – two types are recognized: 1) Sensible-heat polynyas, caused by the upwelling of warmer water and 2) Latent-heat polynyas, resulting from persistent winds from the coastline.[5]

Formation

Satellite image of sea ice forming near St. Matthew Island in the Bering Sea.

Only the top layer of water needs to cool to the freezing point.[10] Convection of the surface layer involves the top 100–150 m (330–490 ft), down to the pycnocline of increased density.

In calm water, the first sea ice to form on the surface is a skim of separate crystals which initially are in the form of tiny discs, floating flat on the surface and of diameter less than 0.3 cm (0.12 in). Each disc has its c-axis vertical and grows outwards laterally. At a certain point such a disc shape becomes unstable, and the growing isolated crystals take on a hexagonal, stellar form, with long fragile arms stretching out over the surface. These crystals also have their c-axis vertical. The dendritic arms are very fragile, and soon break off, leaving a mixture of discs and arm fragments. With any kind of turbulence in the water, these fragments break up further into random-shaped small crystals which form a suspension of increasing density in the surface water, an ice type called frazil or grease ice. In quiet conditions the frazil crystals soon freeze together to form a continuous thin sheet of young ice; in its early stages, when it is still transparent – that is the ice called nilas. Once nilas has formed, a quite different growth process occurs, in which water freezes on to the bottom of the existing ice sheet, a process called congelation growth. This growth process yields first-year ice.

In rough water, fresh sea ice is formed by the cooling of the ocean as heat is lost into the atmosphere. The uppermost layer of the ocean is supercooled to slightly below the freezing point, at which time tiny ice platelets (frazil ice) form. With time, this process leads to a mushy surface layer, known as grease ice. Frazil ice formation may also be started by snowfall, rather than supercooling. Waves and wind then act to compress these ice particles into larger plates, of several meters in diameter, called pancake ice. These float on the ocean surface, and collide with one another, forming upturned edges. In time, the pancake ice plates may themselves be rafted over one another or frozen together into a more solid ice cover, known as consolidated pancake ice. Such ice has a very rough appearance on top and bottom.

If sufficient snow falls on sea ice to depress the freeboard below sea level, sea water will flow in and a layer of ice will form of mixed snow/sea water. This is particularly common around Antarctica.

Russian scientist Vladimir Vize (1886–1954) devoted his life to study the Arctic ice pack and developed the Scientific Prediction of Ice Conditions Theory, for which he was widely acclaimed in academic circles. He applied this theory in the field in the Kara Sea, which led to the discovery of Vize Island.

Yearly freeze and melt cycle

Seasonal variation and annual decrease of Arctic sea ice volume as estimated by measurement backed numerical modelling.[11]
Volume of arctic sea ice over time using a polar coordinate system draw method (time goes counter clockwise; one cycle per year)

The annual freeze and melt cycle is set by the annual cycle of solar insolation and of ocean and atmospheric temperature, and of variability in this annual cycle.

In the Arctic, the area of ocean covered by sea ice increases over winter from a minimum in September to a maximum in March or sometimes February, before melting over the summer. In the Antarctic, where the seasons are reversed, the annual minimum is typically in February and the annual maximum in September or October, and the presence of sea ice abutting the calving fronts of ice shelves has been shown to influence glacier flow and potentially the stability of the Antarctic ice sheet.[12][13]

The growth and melt rate are also affected by the state of the ice itself. During growth, the ice thickening due to freezing (as opposed to dynamics) is itself dependent on the thickness, so that the ice growth slows as the ice thickens.[5] Likewise, during melt, thinner sea ice melts faster. This leads to different behaviour between multiyear and first year ice. In addition, melt ponds on the ice surface during the melt season lower the albedo such that more solar radiation is absorbed, leading to a feedback where melt is accelerated. The presence of melt ponds is affected by the permeability of the sea ice- i.e. whether meltwater can drain- and the topography of the sea ice surface, i.e. the presence of natural basins for the melt ponds to form in. First year ice is flatter than multiyear ice due to the lack of dynamic ridging, so ponds tend to have greater area. They also have lower albedo since they are on thinner ice, which blocks less of the solar radiation from reaching the dark ocean below. [14]

Monitoring and observations

Changes in sea ice conditions are best demonstrated by the rate of melting over time. A composite record of Arctic ice demonstrates that the floes' retreat began around 1900, experiencing more rapid melting beginning within the past 50 years. Satellite study of sea ice began in 1979, and became a much more reliable measure of long-term changes in sea ice. In comparison to the extended record, the sea-ice extent in the polar region by September 2007 was only half the recorded mass that had been estimated to exist within the 1950–1970 period.[15]

Arctic sea ice extent ice hit an all-time low in September 2012, when the ice was determined to cover only 24% of the Arctic Ocean, offsetting the previous low of 29% in 2007. Predictions of when the first "ice free" Arctic summer might occur vary.

Antarctic sea ice extent gradually increased in the period of satellite observations, which began in 1979, until a rapid decline in southern hemisphere spring of 2016.

Relationship to global warming and climate change

As ice melts, the liquid water collects in depressions on the surface and deepens them, forming these melt ponds in the Arctic. These fresh water ponds are separated from the salty sea below and around it, until breaks in the ice merge the two.

Sea ice provides an ecosystem for various polar species, particularly the polar bear, whose environment is being threatened as global warming causes the ice to melt more as the Earth's temperature gets warmer. Furthermore, the sea ice itself functions to help keep polar climates cool, since the ice exists in expansive enough amounts to maintain a cold environment. At this, sea ice's relationship with global warming is cyclical; the ice helps to maintain cool climates, but as the global temperature increases, the ice melts, and is less effective in keeping those climates cold. The bright, shiny surface (albedo) of the ice also serves a role in maintaining cooler polar temperatures by reflecting much of the sunlight that hits it back into space. As the sea ice melts, its surface area shrinks, diminishing the size of the reflective surface and therefore causing the earth to absorb more of the sun's heat. As the ice melts it lowers the albedo thus causing more heat to be absorbed by the Earth and further increase the amount of melting ice.[16] Though the size of the ice floes is affected by the seasons, even a small change in global temperature can greatly affect the amount of sea ice, and due to the shrinking reflective surface that keeps the ocean cool, this sparks a cycle of ice shrinking and temperatures warming. As a result, the polar regions are the most susceptible places to climate change on the planet.[5]

Furthermore, sea ice affects the movement of ocean waters. In the freezing process, much of the salt in ocean water is squeezed out of the frozen crystal formations, though some remains frozen in the ice. This salt becomes trapped beneath the sea ice, creating a higher concentration of salt in the water beneath ice floes. This concentration of salt contributes to the salinated water's density, and this cold, denser water sinks to the bottom of the ocean. This cold water moves along the ocean floor towards the equator, while warmer water on the ocean surface moves in the direction of the poles. This is referred to as "conveyor belt motion", and is a regularly occurring process.[5]


Modelling

In order to gain a better understanding about the variability, numerical sea ice models are used to perform sensitivity studies. The two main ingredients are the ice dynamics and the thermodynamical properties (see Sea ice emissivity modelling, Sea ice growth processes and Sea ice thickness). There are a number of sea ice model computer codes available for doing this, including the CICE numerical suite.

Many global climate models (GCMs) have sea ice implemented in their numerical simulation scheme in order to capture the Ice-albedo feedback correctly. Examples include:

  • The Louvain-la-Neuve Sea Ice Model is a numerical model of sea ice designed for climate studies and operational oceanography developed at Université catholique de Louvain. It is coupled to the ocean general circulation model OPA (Ocean Parallélisé) and is freely available as a part of the Nucleus for European Modeling of the Ocean.
  • The MIT General Circulation Model is a global circulation model developed at Massachusetts Institute of Technology includes a package for sea-ice. The code is freely available there.
  • The University Corporation for Atmospheric Research develops the Community Sea Ice Model.
  • CICE is run by the Los Alamos National Laboratory. The project is open source and designed as a component of GCM, although it provides a standalone mode.
  • The Finite-Element Sea-Ice Ocean Model developed at Alfred Wegener Institute uses an unstructured grid.
  • The neXt Generation Sea-Ice model (neXtSIM) is a Lagrangian model using an adaptive and unstructured triangular mesh, and includes a new and unique class of rheological model called Maxwell-Elasto-Brittle to treat the ice dynamics. This model is developed at the Nansen Center in Bergen, Norway.

The Coupled model intercomparison project offers a standard protocol for studying the output of coupled atmosphere-ocean general circulation models. The coupling takes place at the atmosphere-ocean interface where the sea ice may occur.

In addition to global modeling, various regional models deal with sea ice. Regional models are employed for seasonal forecasting experiments and for process studies.

Ecology

Sea ice is part of the Earth's biosphere. When sea water freezes, the ice is riddled with brine-filled channels which sustain sympagic organisms such as bacteria, algae, copepods and annelids, which in turn provide food for animals such as krill and specialised fish like the Bald notothen, fed upon in turn by larger animals such as Emperor penguins and Minke whales.[17]

A decline of seasonal sea ice puts the survival of Arctic species such as ringed seals and polar bears at risk.[18][19][20]

gollark: I do not think that is how it works.
gollark: Plus they pollute locally and cause !!FUN!! lung problems.
gollark: Obviously.
gollark: Energy storage means you lose a significant bit of your energy to various losses, and generally need large expensive setups of various kinds, some of which degrade over time (e.g. lithium batteries) and some of which are very cool (e.g. superconductive magnetic energy storage).
gollark: Not randomly overvolting stuff seems to pretty much be a solved problem now.

See also

Rare phenomenon – the formation of ball ice. Stroomi Beach, Tallinn, Estonia.

Ice types or features

  • Anchor ice  submerged ice anchored to a river bottom or seafloor
  • Congelation ice  Ice that forms on the bottom of an established ice cover
  • Drift ice  Sea ice that is not attached to land and may move on the sea surface in response to wind and ocean currents
  • Fast ice  Sea ice that is connected to the coastline, to the sea floor along shoals or to grounded icebergs
  • Finger rafting  Compression overlapping of floating ice cover in alternating overthrusts and underthrusts
  • Frazil ice  A collection of loose, randomly oriented, plate or discoid ice crystals formed in supercooled turbulent water
  • Grease ice  A thin, soupy layer of frazil crystals clumped together, which makes the ocean surface resemble an oil slick
  • Iceberg  A large piece of freshwater ice broken off a glacier or ice shelf and floating in open water
  • Ice mélange  A mixture of sea ice types, icebergs, and snow without a clearly defined floe
  • Ice volcano  A conical mound of ice formed over a terrestrial lake via the eruption of water and slush through an ice shelf
  • Lead (sea ice)  A large fracture in sea ice creating a navigable waterway
  • Pancake ice  A form of ice that consists of round pieces of ice with diameters ranging from 30 centimetres (12 in) to 3 metres
  • Polynya  An area of unfrozen sea within ice pack
  • Pressure ridge (ice)  A ridge formed in pack ice by accumulation of ice blocks in the convergence between floes
  • Rotten ice
  • Seabed gouging by ice  A process that occurs when floating ice features drift into shallower areas and their bottom comes into contact with and drags along a softer seabed
  • Slush
  • Stamukha  A grounded pressure ridge that typically develops along the boundary between fast ice and the drifting pack ice
  • Sastrugi, also known as Zastruga  Sharp irregular grooves or ridges formed on a snow surface

Physics and chemistry

Applied sciences and engineering endeavours

References

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  2. Weeks, Willy F. (2010). On Sea Ice. University of Alaska Press. p. 2. ISBN 978-1-60223-101-6.
  3. Shokr, Mohammed; Sinha, Nirmal (2015). Sea Ice - Physics and Remote Sensing. John Wiley & Sons, Inc. ISBN 978-1119027898.
  4. Leppr̃anta, Matti (2005). The Drift of Sea Ice. Springer. ISBN 978-3-540-40881-9.
  5. NSIDC All About Sea Ice
  6. Environment Canada Ice Glossary
  7. WMO Sea-Ice Nomenclature
  8. Murray, Jessica (7 November 2019). "Thousands of rare 'ice eggs' found on beach in Finland". The Guardian.
  9. Wadhams, P. (2000). Ice in the Ocean. CRC Press. ISBN 978-90-5699-296-5.
  10. Barry, Roger G.; Blanken, Peter D. (2016). Microclimate and Local Climate. Cambridge University Press. p. 189. ISBN 978-1-316-65233-6.
  11. Zhang, Jinlun; Rothrock, D. A. (May 2003). "Modeling global sea ice with a thickness and enthalpy distribution model in generalized curvilinear coordinates". Mon. Wea. Rev. 131 (5): 845–861. Bibcode:2003MWRv..131..845Z. CiteSeerX 10.1.1.167.1046. doi:10.1175/1520-0493(2003)131<0845:MGSIWA>2.0.CO;2.
  12. Greene, Chad A.; Young, Duncan A.; Gwyther, David E.; Galton-Fenzi, Benjamin K.; Blankenship, Donald D. (6 September 2018). "Seasonal dynamics of Totten Ice Shelf controlled by sea ice buttressing". The Cryosphere. 12 (9): 2869–2882. Bibcode:2018TCry...12.2869G. doi:10.5194/tc-12-2869-2018. ISSN 1994-0416.
  13. Massom, Robert A.; Scambos, Theodore A.; Bennetts, Luke G.; Reid, Phillip; Squire, Vernon A.; Stammerjohn, Sharon E. (2018). "Antarctic ice shelf disintegration triggered by sea ice loss and ocean swell". Nature. 558 (7710): 383–389. Bibcode:2018Natur.558..383M. doi:10.1038/s41586-018-0212-1. ISSN 0028-0836. PMID 29899449.
  14. Perovich, Donald (2017). "Chapter 4: Sea Ice and Sunlight". In Thomas, David (ed.). Sea Ice (3 ed.). Wiley-Blackwell.
  15. Polyak, Leonid; Richard B. Alley; John T. Andrews; Julie Brigham-Grette; Thomas M. Cronin; Dennis A. Darby; et al. (3 February 2010). "History of sea ice in the Arctic" (PDF). Quaternary Science Reviews. 29 (15): 2–17. Bibcode:2010QSRv...29.1757P. doi:10.1016/j.quascirev.2010.02.010.
  16. "Albedo". Climate Education Modules for K-12. NC State University. Archived from the original on 29 May 2017. Retrieved 15 November 2017.
  17. "Sea Ice Ecology". Sea Ice Physics and Ecosystem eXperiment (SIPEX). Antarctic Climate & Ecosystems CRC. Archived from the original on 20 March 2012. Retrieved 23 June 2012.
  18. Barber, D. G.; Iacozza, J. (March 2004). "Historical analysis of sea ice conditions in M'Clintock Channel and the Gulf of Boothia, Nunavut: implications for ringed seal and polar bear habitat". Arctic. 57 (1): 1–14. doi:10.14430/arctic478. JSTOR 40512590.
  19. Stirling, I.; Lunn, N. J.; Iacozza, J.; Elliott, C.; Obbard, M. (March 2004). "Polar bear distribution and abundance on the southwestern Hudson Bay coast during open water season, in relation to population trends and annual ice patterns". Arctic. 57 (1): 15–26. doi:10.14430/arctic479. JSTOR 40512591.
  20. Stirling, I.; Parkinson, C. L. (September 2006). "Possible effects of climate warming on selected populations of polar bears (Ursus maritimus) in the Canadian Arctic" (PDF). Arctic. 59 (3): 261–275. doi:10.14430/arctic312. hdl:2060/20060020227. JSTOR 40512813.

Sea ice glossaries

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