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By Peter Rejcek
In 2005, scientists aboard the ARSV Laurence M. Gould
went on what pelagic biologist Bruce Robison said some
in the scientific community characterized as a quixotic
quest to prove icebergs are a hotspot for life in the
deep ocean.
The team of geochemists, oceanographers, biologists and
others indeed found a host of animals and organisms above,
below and on the icebergs, including seabirds, phytoplankton
and shrimp-like krill. But they also believe these floating
chunks of ice may play a significant role in removing
carbon dioxide from the atmosphere thanks to the associated
biological community. The research culminated with the
publication of the team’s paper in the journal “Science”
last year.
Now many of the same members of that group are returning
to the Weddell Sea at the end of May for a one-month science
cruise aboard the RVIB Nathaniel B. Palmer to further
study how icebergs affect the marine ecosystem. A second
cruise is planned for March 2009.
So how can a block of ice, even one as big as Manhattan
Island, give birth to a diverse biological community,
one that can extend as much as 4 kilometers from the iceberg?
It turns out these icebergs, made of glacial ice that
once ground against bedrock, hold terrestrial materials
that contain traces of micronutrients including iron,
which it drops like breadcrumbs into the sea as it melts.
Iron helps create blooms of phytoplankton, mostly composed
of algae, which absorb carbon dioxide (CO2) from the atmosphere.
Some of that carbon will return to the atmosphere, but
much of it will sink into the deep ocean, when the algae
die, removing carbon from the system for hundreds if not
thousands of years. CO2 is a key greenhouse gas.
“We’re trying to look at how much organic carbon
is basically produced by the phytoplankton and how much
escapes into the deep ocean,” explained oceanographer
Ken Smith, the project’s principal investigator from
California-based Monterey Bay Aquarium Research Institute
(MBARI).
The researchers also want to determine how much iron
the icebergs deposit in the ocean as they migrate, as
well as how the micronutrient promotes phytoplankton growth
and photosynthesis.
A well-known theory called the Iron Hypothesis, put forward
by oceanographer John Martin in the 1980s, says that some
areas of the oceans contain the major nutrients required
for aquatic plant growth — nitrate and phosphate.
What’s lacking are the micronutrients like iron.
Scientists call these areas of the ocean, including the
Southern Ocean, high nutrient low chlorophyll regions.
One save-the-planet theory, put forward by Martin and
others, suggests seeding the ocean with iron to increase
phytoplankton blooms, which would soak in more CO2, presumably
lowering the amount of the greenhouse gas in the atmosphere
and subsequently lowering temperatures. It’s sort
of like adding Miracle Grow® to your garden to improve
plant growth.
Timothy Shaw, a geochemist from the University of South
Carolina, said it appears the icebergs can provide iron
and other micronutrients from the terrestrial material
they carry. On the 2005 cruise, he and his group measured
isotopes of radium, including radium 224, that they collected
from the seawater around two icebergs.
Radium is ubiquitous in terrestrial material, he explained,
so the scientists used it as a proxy for determining the
presence of iron and other micronutrients like zinc, which
would also be present in terrestrial material. The radioisotope
radium 224 has a half-life of 3.6 days, Shaw said.
“So, if we could measure it around icebergs, we
were sure that it wasn’t a long-distance source,”
he said. “The half-life is so short that you can’t
have it transported long distances from continents.”
The half-life is the amount of time it takes for half
of the atoms in a sample to decay.
The icebergs become an intermediary between the terrestrial
and ocean systems, what Shaw called a Lagrangian estuary,
a moving source of biological diversity. “This kind
of fits the model of a moving estuary,” said Shaw,
a co-principal investigator on the project.
On the two trips to the Weddell Sea, Shaw and his group
will “map the inventories of particulate material,
radioisotopes and iron to validate our contention that
icebergs deliver a tremendous amount of terrestrial material.”
To make that and other determinations about iceberg characteristics,
the researchers will use a number of tools, including
a device developed by Scripps Institution of Oceanography
called a SOLO float. The SOLO float, which stands for
Sounding Oceanographic Lagrangian Observer, can dive up
to 2 kilometers deep in the upper ocean, taking temperature,
depth and salinity readings as it moves up and down in
the water based on a set of instructions encoded in its
electronics package.
Thousands of these floats have been deployed in the oceans.
For the Palmer cruise in June, the researchers will send
several SOLO floats underneath the icebergs they study.
“What we’ve done is just borrow that technology,”
Smith said. “We got people at Scripps to build us
several of these SOLO floats, and we secured inverted
cones on them, so they’re like rain gauges. They
just collect material as it settles through the water
column.
“The intent of that is to collect the carbon that is
being produced by the community,” he added. “This
gives us a handle on how much carbon is escaping the upper
water system. We’re hopefully looking at how much carbon
is being consumed by the enriched community, and how much
of that carbon as organic matter is being exported out of
the photic zone to the deep sea.”
It’s in the photic zone where photosynthesis occurs,
when sunlight penetrates the upper ocean. The high amount
of phytoplankton biomass found around the icebergs in
2005 was similar to that found near the edge of seasonal
pack ice or during iron enrichment experiments like that
proposed by Martin, the scientists reported in the “Science”
paper.
Another key tool in the team’s arsenal is a remotely
operated vehicle (ROV) tethered to the Palmer. Robison,
the pelagic biologist, also from MBARI, is the primary
ROV pilot. He said engineers have substantially modified
the robot from when the scientists used it three years
ago.
They added two thrusters and a tool sled that allows
the ROV to carry more instruments. They also upgraded
its cameras, and outfitted it with a new, longer tether
so the versatile little robot can explore the bottom of
icebergs while the ship maintains a safe distance, about
300 meters.
“It’s a little hairy getting too close to these
big icebergs, because they calve and thousands of tons
of ice can come falling into the ocean unannounced,”
Robison said. “For those wanting to work in close,
the only way to get in there, to see things and make measurements
and collections, is with a remotely operated vehicle.
“We’ve tricked it out with all types of gear,”
added Robison, a co-principal investigator on the project.
“When we got a peek around the corner [in 2005],
so to speak, we couldn’t do any exploring underneath,
and that’s something we’re looking forward to
this time with the longer tether.”
But thanks to the ROV in 2005, the team made another
particularly provocative discovery, despite the robot’s
limited range. They found “tufts” of algae adhering
to the iceberg where sand-grain-sized volcanic rocks were
embedded in the ice. In addition, the surface of the iceberg
resembled a uniformly flattened golf ball, with the algae
growing around the edges of the dimples, which were about
6 to 8 centimeters wide and about 2 centimeters deep.
“It was a significant discovery. Something no one
had seen before,” Robison said. “Krill were
feeding on [the tufts of algae] extensively.” Added
Smith, “There are huge fields of these things in
the light zone.”
The algae, made up mostly of diatoms, resembled that
found in benthic communities in shallow subtidal zones.
The scientists estimated that these algae might inhabit
as much as 25 percent of the submerged portion of an iceberg.
That represents a significant source of primary plant
production — and another source for sucking CO2 out
of the atmosphere — considering the number of icebergs
floating along in the Southern Ocean.
In fact, using satellite images, the researchers counted
nearly 1,000 icebergs in an 11,000-square-kilometer area
of ocean. They calculated that in 40 percent of the Weddell
Sea the icebergs are raising biological productivity.
It’s not unreasonable, Robison said, to hypothesize
that icebergs are spawning similar productivity in other
areas around the Southern Ocean. The idea seems incredible
— that there are literally thousands of these floating
estuaries sucking CO2 out of the air like a straw —
until one considers what the researchers have already
discovered.
It all began with a simple observation, according to
Robison.
“One thing that you can’t help but notice is
that anytime anything floats in the ocean — whether
it’s a clump of seaweed or an old bottle or a wooden
raft — eventually animal communities build up around
it. Barnacles attach, some plankton goes there for shelter,
and big fish hang out there to feed on the plankton,”
he explained.
“With the icebergs increasing, chances are that
would have an effect on these pelagic communities,”
Robison added. “These ideas come from lots of experience
of looking at the ocean, scratching your head, and trying
to figure out what’s going on and how does this work?
And what am I missing?”
Perhaps the better question to ask: What are they going
to find next?
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