. The others are the
atmosphere, the
hydrosphere, the
lithosphere and the
biosphere.There are several fundamental physical properties of snow and ice that modulate energy exchanges between the surface and the
atmosphere. The most important properties are the surface reflectance (
albedo), the ability to transfer heat (thermal diffusivity), and the ability to change state (
latent heat). These physical properties, together with surface roughness,
emissivity, and
dielectric characteristics, have important implications for observing snow and ice from space. For example, surface roughness is often the dominant factor determining the strength of
radar backscatter. Physical properties such as
crystal structure, density, length, and liquid water content are important factors affecting the transfers of heat and water and the scattering of
microwave energy.
Residence time and extent The residence time of water in each of the cryospheric sub-systems varies widely. Snow cover and freshwater ice are essentially seasonal, and most sea ice, except for ice in the central
Arctic, lasts only a few years if it is not seasonal. A given water particle in glaciers, ice sheets, or ground ice, however, may remain frozen for 10–100,000 years or longer, and deep ice in parts of
East Antarctica may have an age approaching 1 million years. Most of the world's ice volume is in
Antarctica, principally in the
East Antarctic Ice Sheet. In terms of areal extent, however,
Northern Hemisphere winter snow and ice extent comprise the largest area, amounting to an average 23% of hemispheric surface area in January. The large areal extent and the important climatic roles of snow and
ice is related to their unique physical properties. This also indicates that the ability to observe and model snow and ice-cover extent, thickness, and radiative and thermal properties is of particular significance for
climate research.
Surface reflectance The surface reflectance of incoming
solar radiation is important for the surface energy balance (SEB). It is the ratio of reflected to incident solar radiation, commonly referred to as
albedo. Climatologists are primarily interested in albedo integrated over the
shortwave portion of the
electromagnetic spectrum (~300 to 3500 nm), which coincides with the main solar energy input. Typically, albedo values for non-melting snow-covered surfaces are high (~80–90%) except in the case of forests. The higher albedos for snow and ice cause rapid shifts in surface
reflectivity in autumn and spring in high latitudes, but the overall climatic significance of this increase is spatially and temporally modulated by
cloud cover. (Planetary albedo is determined principally by cloud cover, and by the small amount of total solar radiation received in high
latitudes during winter months.) Summer and autumn are times of high-average cloudiness over the
Arctic Ocean so the albedo
feedback associated with the large seasonal changes in sea-ice extent is greatly reduced. It was found that snow cover exhibited the greatest influence on
Earth's radiative balance in the spring (April to May) period when incoming
solar radiation was greatest over snow-covered areas.
Thermal properties of cryospheric elements The
thermal properties of cryospheric elements also have important climatic consequences. Snow and ice have much lower thermal diffusivities than
air.
Thermal diffusivity is a measure of the speed at which temperature waves can penetrate a substance. Snow and ice are many
orders of magnitude less efficient at diffusing heat than air. Snow cover insulates the ground surface, and sea ice insulates the underlying ocean, decoupling the surface-atmosphere interface with respect to both heat and moisture fluxes. The flux of moisture from a water surface is eliminated by even a thin skin of ice, whereas the flux of heat through thin ice continues to be substantial until it attains a thickness in excess of 30 to 40 cm. However, even a small amount of snow on top of the ice will dramatically reduce the heat flux and slow down the rate of ice growth. The insulating effect of snow also has major implications for the
hydrological cycle. In non-permafrost regions, the insulating effect of snow is such that only near-surface ground freezes and deep-water drainage is uninterrupted. While snow and ice act to insulate the surface from large energy losses in winter, they also act to retard warming in the spring and summer because of the large amount of energy required to melt ice (the
latent heat of fusion, 3.34 × 105 J/kg at 0 °C). However, the strong static stability of the atmosphere over areas of extensive snow or ice tends to confine the immediate cooling effect to a relatively shallow layer, so that associated atmospheric anomalies are usually short-lived and local to regional in scale. In some areas of the world such as
Eurasia, however, the cooling associated with a heavy snowpack and moist spring soils is known to play a role in modulating the summer
monsoon circulation.
Climate change feedback mechanisms There are numerous cryosphere-climate feedbacks in the
global climate system. These operate over a wide range of spatial and temporal scales from local seasonal cooling of air temperatures to hemispheric-scale variations in ice sheets over time scales of thousands of years. The feedback mechanisms involved are often complex and incompletely understood. For example, Curry
et al. (1995) showed that the so-called "simple" sea ice-albedo feedback involved complex interactions with lead fraction, melt ponds, ice thickness, snow cover, and sea-ice extent. The role of snow cover in modulating the monsoon is just one example of a short-term cryosphere-climate feedback involving the land surface and the atmosphere. == Components ==