The 200-foot-tall (60-meter-tall) front of the Getz Ice Shelf in Antarctica
is scored with cracks where icebergs are likely to break off, or calve, in this
2016 photo. The first estimate of Antarctic calving has found that since 1997
ice shelves have lost as much ice from calving as from melting. Credits:
NASA/GSFC/OIB
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New research on Antarctica, including the first map of iceberg calving, doubles the previous estimates of loss from ice shelves and details how the continent is changing.
The greatest uncertainty in forecasting
global sea level rise is how Antarctica’s ice loss will accelerate as the
climate warms. Two studies published Aug. 10 and led by researchers at NASA’s
Jet Propulsion Laboratory in Southern California reveal unexpected new data
about how the Antarctic Ice Sheet has been losing mass in recent decades.
One study,
published in the journal Nature,
maps how iceberg calving – the breaking off of ice from a glacier front – has
changed the Antarctic coastline over the last 25 years. The researchers found
that the edge of the ice sheet has been shedding icebergs faster than the ice
can be replaced. This surprise finding doubles previous estimates of ice loss
from Antarctic’s floating ice shelves since 1997, from 6 trillion to 12
trillion metric tons. Ice loss from calving has weakened the ice shelves and
allowed Antarctic glaciers to flow more rapidly to the ocean, accelerating the
rate of global sea level rise.
The other study, published in Earth System Science Data, shows in unprecedented detail how the
thinning of Antarctic ice as ocean water melts it has spread from the
continent’s outward edges into its interior, almost doubling in the western
parts of the ice sheet over the past decade. Combined, the complementary
reports give the most complete view yet of how the frozen continent is changing.
Changes in elevation of the Antarctic ice sheet from 1985 to 2021 are
shown. Ice height diminishes (red) as the ice sheet melts by contact with ocean
water; it rises (blue) where accumulation exceeds melting. Ice shelves are
shown in gray. The missions that supplied data are listed at bottom. Credits:
NASA/JPL-Caltech
Iceberg Calving
“Antarctica is crumbling at its edges,” says JPL scientist Chad Greene,
lead author of the calving study. “And when ice shelves dwindle and weaken, the
continent’s massive glaciers tend to speed up and increase the rate of global
sea level rise.”
Most Antarctic glaciers flow to the ocean, where they end in floating ice
shelves up to 2 miles (3 kilometers) thick and 500 miles (800 kilometers)
across. Ice shelves act like buttresses to glaciers, keeping the ice from
simply sliding into the ocean. When ice shelves are stable, they have a natural
cycle of calving and replenishment that keeps their size fairly constant over
the long term.
But in recent decades, the warming ocean has been destabilizing
Antarctica’s ice shelves by melting them from below, making them thinner and
weaker. Satellite altimeters measure the thinning process by recording the
changing height of the ice, but until this study, there hasn’t been a
comprehensive assessment of how climate change might be affecting calving
around the continent.
That’s partly because satellite imagery has been challenging to interpret.
“For example,” said Greene, “you can imagine looking at a satellite image and
trying to figure out the difference between a white iceberg, white ice shelf,
white sea ice, and even a white cloud. That’s always been a difficult task. But
we now have enough data from multiple satellite sensors to see a clear picture
of how Antarctica’s coastline has evolved in recent years.”
For the new study, Greene and his co-authors synthesized satellite imagery
of the continent in visible, thermal infrared (heat), and radar wavelengths
since 1997. Combining these measurements with an understanding of ice flow
gained from an ongoing NASA glacier-mapping project, they charted the edges of ice shelves around 30,000 linear miles (50,000
kilometers) of Antarctic coastline.
Losses from calving have outpaced natural ice-shelf growth so greatly that
the researchers think it’s unlikely Antarctica can grow back to its pre-2000
extent by the end of this century. In fact, the findings suggest that greater
losses can be expected: Antarctica’s largest ice shelves all appear to be
headed for major calving events in the next 10 to 20 years.
Mapping 36 Years of Ice Loss
In the complementary study, JPL scientists have combined almost 3 billion
data points from seven spaceborne altimetry instruments to produce the longest
continuous data set on the changing height of the ice sheet – an indicator of
ice loss – from as early as 1985. They used radar and laser measurements of ice
elevation, accurate to within centimeters, to produce the highest-resolution
monthly maps of change ever made of ice loss.
The unparalleled detail in the new record reveals how long-term trends and
annual weather patterns affect the ice. It even shows the rise and fall of the
ice sheet as subglacial lakes regularly fill and empty miles below the surface. “Subtle changes like these, in combination
with improved understanding of long-term trends from this data set, will help
researchers understand the processes that influence ice loss, leading to
improved future estimates of sea level rise,” said JPL’s Johan Nilsson, lead
author of the study.
Synthesizing and analyzing the massive archives of measurements into a
single, high-resolution data set took years of work and thousands of hours of
computing time on NASA’s servers. Nilsson says it was all worth it: “Condensing
the data into something more widely useful may bring us closer to the big
breakthroughs we need to better understand our planet and to help prepare us
for the future impacts of climate change.”
Jane J. Lee / Andrew Wang
Jet Propulsion Laboratory, Pasadena, Calif.
Written by Carol Rasmussen
Source: NASA
Studies Find Previously Unknown Loss of Antarctic Ice | NASA
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