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IMAGES OF THE LARSEN ICE SHELF AND THE MECHANISMS OF CHANGE
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Zooming in for a Closer
Look
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The Larsen Ice Shelf is
one of a number of shelves on the southernmost continent. Looking at
it from above, the region lies on the eastern side of the
northernmost peninsula, a stretch of land pointing towards South
America.
In 1995 alone, a region
of ice on the Larsen Ice Shelf more than two-thirds the size of
Rhode Island disintegrated in a fierce storm. Additional ice broke
away from the rest of the shelf in 1998. This dramatic change to so
much ice is the product of several forces acting in concert. In this
visualization we start with an overall picture of the continent and
zoom in to the specific area of study.
These images are the product of
the Landsat 7 satellite. They are provided courtesy of NASA/USGS.
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Surface Water
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This image shows
a section of the remaining Larsen Ice Shelf. The dark patches
scattered around the white background are regions of surface melt
water, formed during the summer season. It’s from these pools that
water drained into cracks in the shelf to form the wedges that
ultimately shattered the ice. NASA’s Landsat 7 spacecraft took
this picture on February 21, 2000.
Images
courtesy: NASA/USGS
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Before and After
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image from 1993 TIFF
image from 1993
Large
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from 2000
The Larsen Ice Shelf is one of
several so-called ice shelves in Antarctica. Although not the
largest, experts consider it to be most in jeopardy of further
recession due to its comparatively northern position. In this
sequence, we see how the ice there has changed through time,
starting in December 1993 and ending in March 2000.
These images are the product of NOAA’s
AVHRR instrument, (Advanced Very High Resolution Radiometer), flying
aboard that agency’s POES (Polar Orbiting Environmental
Spacecraft) satellite.
The POES spacecraft took the images
used to create this sequence on the following dates:
December 26, 1993, February 13, 1995,
March 21, 1998, November 21, 1998, March 2, 2000.
Images courtesy: NOAA/NASA
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A Process of Change:
What Happened to Shatter the Ice
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The mechanism
that rends vast stretches of Antarctic ice from its moorings is
similar to what causes roads to crack in late winter.
Cracks form in the ice
shelf for a number of reasons. But crevasses often appear along the
landward side of the shelf as ice moving in glaciers grinds past
features on the coast and plows into the ice on the shelf.
As melting water on the
surface of the shelf fills in those fissures and crevasses, pressure
builds in the structure of the sheet. That process can either
increase gradually, or it can be repeated seasonally. What happens is
a gradual splintering of a wide section of shelf, which is then
ultimately rent asunder by tides or storms.
The process is
believed to be more a function of mean summertime temperatures, as
opposed to overall annual temperatures.
Antarctica’s ice
shelves account for about two percent of all ice found there.
Experts say that advance and retreat of those shelves usually happen
in terms of decades, not individual years.
These images are the product of
the Landsat 7 satellite. They are provided courtesy of NASA/USGS.
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A Look at the
Retreating Ice Sheet
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We start this animation
with a look at Antarctica’s ice pack as it appears today. Then the
scene changes to describe how the continent likely looked at the
peak of the last ice age, nearly 20,000 years ago. As the years roll
backwards in a matter of seconds, we see just how significantly the
area can be altered as planetary conditions change.
As the animation cycles
back to the present, consider that since the last ice age, the
west Antarctic ice sheet has lost nearly two thirds of its mass
during this period, a volume of ice sufficient to raise sea levels
approximately 33 feet around the globe.
Images courtesy:
NASA
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A TOUR
OF SEVERAL ANTARCTIC ICE SHEETS
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The largest of the ice
shelves in Antarctica is the Ross. Its thickness varies from six
hundred feet to as much as three thousand in places; it covers an
area approximately as large as France. The Ross catches the outflow
of major glaciers and ice streams, draining ice from the continent’s
interior. Experts caution that a massive collapse of the Ross Ice
Shelf could have measurable effects on global sea levels.
This image is the product of
the Canadian Space Agency's RADARSAT satellite. They are
provided courtesy of NASA, the Canadian Space Agency, and Ohio State
University.
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LARSEN ICE SHELF –
Another comparison
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In 1978, scientists
predicted that global warming would lead to a disintegration of
Antarctic Peninsula ice shelves. Spaceborne data indicate that this
prediction may be coming true. In these before and after images, note
the dramatic change in the apparent shoreline. Scientists captured the
first image in using the ERS-1 satellite in 1992. As seen in the
second image, collected by RADARSAT in 1997, huge changes have come to
the coastline. Notice how the once attached expanse of ice that was
Larsen became thousands of floating shards and icebergs, drifting out
to sea.
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FIMBUL ICE SHELF
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Icebergs form when hunks of ice
break away from glaciers pushing into the ocean. Ice shelves are
the edges of those glaciers, extending out into the ocean faster than ice
bergs can break off from the edge. The Fimbul Ice Shelf has remained
relatively consistent in its appearance for the last thirty years, but
researchers are paying close attention to changes. Ice shelves are
considered to be particularly sensitive to climatic changes and
scientists have detected a marked retreat along the
Antarctic Peninsula. Note the fascinating formations along the
Fimbul, believed to be the product of glacial ice flowing over
rocky outcroppings and islands.
These images are the product of the
Canadian Space Agency's RADARSAT satellite. They are
provided courtesy of NASA, the Canadian Space Agency, and Ohio
State University.
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AMERY ICE SHELF
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At the mouth of the Lambert Glacier
spreads the Amery Ice Shelf. For the most part, ice shelves grow
from glaciers pushing down into the sea. They
also grow from precipitation. Ice Shelves respond to climate
change faster than sheets of ice on the ground or continental
glaciers. Scientists hope that continued study of ice shelves like
Amery will help them better understand what sorts of changes are
happening to the world’s climate in general. Of particular
interest is whether observed changes in various ice shelves are
the result of natural processes or are anthropogenic, that is, the
result of actions taken by humans.
These images are the product of the
Canadian Space Agency's RADARSAT satellite. They are
provided courtesy of NASA, the Canadian Space Agency, and
Ohio State University.
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RONNE ICE SHELF
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The Ronne Ice Shelf
grows primarily due to a constant flow from inland ice sheets. Where
shearing stresses are greater than the strength of the ice itself,
cracks form. These cracks ultimately widen and spread like varicose
veins in the frozen skin of the coast, only to break loose and
become icebergs. Early in the 1990’s a slab of ice the size of
Delaware broke free from this area. A recent iceberg more than 40
miles wide now floating in the South Atlantic originated from the
Ronne Ice Shelf.
Interestingly, as ice
shelves break up into icebergs, the sea level generally doesn’t
rise. That’s because ice shelves are ostensibly floating in the
water already. That floating ice, connected to the shore by ice
sheets and glaciers, displaces a volume of water equal to the volume
of water contained in the shelf. When a berg breaks off, or calves,
there is no new water to displace. It simply separates from
shore...and goes on its way.
These images are the product of
the Canadian Space Agency's RADARSAT satellite. They are
provided courtesy of NASA, Canadian Space Agency, and Ohio State
University.
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Landsat 7—Keeping
an Eye on the Earth’s Changing Face
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From an altitude of 438 miles (730
kilometers), Landsat 7 can see surface features as small as 15
meters, providing world-wide land resource information for a diverse
range of uses. The satellite is part of a global research effort
NASA calls the Earth Science Enterprise, which seeks to acquire a
long term understanding of the changes to our planet. Landsat 7 is
the latest in a series of satellites. It roared into orbit aboard a
Boeing Delta II rocket on April 15, 1999 from Vandenberg Air Force
Base in California. NASA officially called the first Landsat
satellite the Earth Resources Technology Satellite, or ERTS-1, on
July 23, 1972. Since then the program has continued to pave the way
in research and data acquisition techniques about the surface of our
planet.
Images courtesy: NASA/USGS
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THE RADARSAT SATELLITE
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NASA launched the RADARSAT
satellite for the Canadian Space Agency in exchange for
certain operational executions. Unlike mapping satellites that rely
on reflected sunlight or infrared readings, RADARSAT’s Synthetic
Aperture Radar (SAR) is able to penetrate cloud cover or work in the
dark of night.
Courtesy: NASA/Canadian Space
Agency
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