Polar Regions : Climate Change Impacts Introduction

Arctic Melting: Greenland Ice Cap

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Polar Regions

Historical Background and Scientific Foundations

Arctic Melting: Greenland Ice Cap
Introduction
Greenland is an island in the North
Atlantic Ocean
. With an area of
about 836,000 sq mi (2,166,000 sq km), mostly above the
Arctic Circle
,
Greenland is by far the world's largest island, over twice the size of
New
Guinea
. Politically, it is a territory of Denmark and has a population of
about 57,000 people. Over 80% of the island is covered by an ice sheet
with an average thickness of about 1 mi (1.6 km), but the ice sheet is
twice this thick in its central area. There are also a number of large
glaciers and smaller ice caps around the periphery of the island. The
total amount of ice stored in the cap is 964,000 cubic mi (4 million cubic
km), 10% of all the ice on the planet (most of the rest is in the Antarctic
ice sheet). If the Greenland
ice cap
were to melt completely, scientists
estimate that the resulting meltwater would raise global sea levels by
about 21 ft (6.5 m, with many experts estimating 7 m). Although most
scientists presently assert that the complete melting of the Greenland
ice
cap
is not likely to occur in the next century or so, in recent years greatly
accelerated melting of this ice cap due to
global warming
has been
measured.
Historical Background and Scientific Foundations
The Greenland ice sheet, like that of Antarctica, is formed of layers of
annual snowfall that pack down into solid ice, each year building on the
previous year. Eventually, after many millennia, the ice sheet becomes
heavy enough to spread or flow under the force of its own weight,
causing glaciers to flow downhill to the sea. As of 2007, the oldest ice
that had been recovered by drilling into the Greenland ice sheet was
about 123,000 years old, but the ice cap as a whole is much older. It is a
leftover from the Pleistocene glaciation, which covered a large part of
the Northern Hemisphere with thick glaciers from about 1,800,000 years
ago to 11,500 years ago.
Scientific knowledge of Greenland's ice was limited until the 1970s,
when Denmark, the
United States
, and Switzerland organized the
Greenland Ice Sheet Program to obtain ice cores from the sheet. Ice
cores are cylinders of ice obtained by drilling vertically downward with
a hollow device especially designed to return undamaged pieces of ice to

the surface. As of 2007, the longest such cores from Greenland recorded
123,000 years of snow layering; in Antarctica, the longest cores
recorded some 880,000 years. Ice bubbles trapped in these cores give
data on local snowfall rates, and ratios of atomic isotopes in the trapped
water indicate global warmth over time. Evidence of global lead
pollution by the Greek and Roman civilizations has even been found in
Greenland ice cores.
Ice floating on the seas, such as the north polar ice pack, does not raise
sea level
when it melts. Each piece of melting ice can be visualized as
simply filling in the hollow it makes in the water as it floats. However,
the ice locked in the Greenland and Antarctic ice sheets, because it is
sitting on land, does raise sea levels when it melts. The amount of
freshwater running off of Greenland into the sea can also affect the
thermohaline or conveyor-belt circulation of the oceans, which
transports warm water in surface currents to
the Arctic
and Antarctic and
returns it to the tropics in cool currents deeper in the ocean. This, in turn,
affects climate patterns worldwide.
Measuring the amount of ice in Greenland is not an easy matter. The ice
sheet is vast (almost as large as Mexico), accessible only by air over
large areas, and of uneven thickness. In the 1990s, surface-height
changes of the Greenland ice mass, which show gain or loss of ice, were
made using laser altimeters (altitude-measuring devices) carried in
airplanes. Repeated measurements were compared to each other to
detect changes over time. As of 2000, these data indicated that the
higher-altitude (above 6,560 ft/2,000 m), thicker part of the ice sheet—
which totals 70% of the ice sheet—was in approximate balance, gaining
mass from snow and losing it from melting at about equal rates. Seventy
percent of the sheet area below 6,560 ft (2,000 m) was losing mass, but
not very rapidly. These data from the 1990s indicated that the ice mass
of Greenland was in approximate balance, with snowfall gains in the
southwest balanced by melting in the southeast. The amount of water
added to the oceans by Greenland ice loss was calculated to be
contributing about 7% of observed sea-level rise, that is, about 0.005 in
(0.13 mm) per year.

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