It is easy to overlook the small when investigating the carbon budget
of the biome. The actual mass easily far exceeds what is obvious.
Thus we see a continuous down flux of rich carbon based food to the
ocean bottom although surely a lot of that is just as efficiently
reabsorbed and reprocessed. Some of it may well even make it back up
as methane rather quickly.
What is important is that the sea bottom sea surface cycle will turn
out to be remarkably robust and modestly interacting with the
atmosphere. Sunlight and CO2 is feeding it just as it feeds the land
surface. It should be obvious that additional nitrification will
accelerate draw down of CO2 frfom the atmosphere.
In the long term we need to think about that a little more. My best
option is to suspend a neutral pipe into the nutrient rich deep and
allow natural pressure to hurl water into the surface at well picked
locations. This also could be used to suppress hurricane development
as the surface would be also chilled a little. I would particularly
take advantage of the Midatlantic Ridge if that is possible and any
other sea mounts that provide convenient anchoring points
Small fish can play
a big role in the coastal carbon cycle
by David Malmquist
Gloucester Point VA (SPX) Oct 11, 2012
A study in this week's
issue of Scientific Reports, a new online journal from the Nature
Publishing Group, shows that small forage fish like anchovies can
play an important role in the "biological pump," the
process by which marine life transports carbon dioxide from the
atmosphere and surface ocean into the deep sea-where it contributes
nothing to current global warming.
The study, by Dr. Grace Saba of Rutgers University and professor
Deborah Steinberg of the Virginia Institute ofMarine Science,
reports on data collected on an oceanographic expedition to the
California coast during Saba's graduate studies at VIMS. Saba, now a
post-doctoral researcher in Rutgers' Institute of Marine and Coastal
Sciences, earned her Ph.D. from the College of William and Mary's
School of Marine Science at VIMS in 2009.
The expedition, aboard
the research vessel Point Sur, was funded by the National Science
Foundation.
The study's focus on
fish is a departure for Steinberg and colleagues in her Zooplankton
Ecology Lab, who typically study tiny crustaceans called copepods.
Research
by Steinberg's team during the last two decades has revealed that
copepods and other small, drifting marine animals play
a key role in the biological pump by grazing on photosynthetic algae
near the sea surface, then releasing the carbon they've ingested as
"fecal pellets" that can rapidly sink to the deep ocean.
The algal cells are themselves generally too small and light to sink.
"'Fecal pellet'
is the scientific term for "poop," laughs Steinberg.
"Previous studies in our lab and by other researchers show that
zooplankton fecal pellets can sink at rates of hundreds to thousands
of feet per day, providing an efficient means of moving carbon to
depth. But there have been few studies of fecal pellets from fish,
thus the impetus for our project."
Saba says, "We
collected fecal pellets produced by northern anchovies, a forage
fish, in the Santa Barbara Channel off the coast of southern
California." She determined that sinking rates for the
anchovies' fecal pellets average around 2,500 feet per day,
extrapolating from the time required for pellets to descend through a
cylinder of water during experiments in the shipboard lab.
At that rate, says
Saba, "pellets produced at the surface would travel the 1,600
feet to the seafloor at our study site in less than a day."
Saba and Steinberg
also counted the pellets' abundance-up to 6 per cubic meter of
seawater, measured their carbon content-an average of 22 micrograms
per pellet, and painstakingly identified their partly digested
contents-mostly single-celled algae like dinoflagellates and diatoms.
"Twenty
micrograms of carbon might not seem like much," says Steinberg,
"but when you multiply that by the high numbers of forage fish
and fecal pellets that can occur within nutrient-rich coastal zones,
the numbers can really add up."
Saba and Steinberg
calculate that the total "downward flux" of carbon within
fish fecal pellets at their study site reached a maximum of 251
milligrams per square meter per day-equal to or greater than
previously measured values of sinking organic matter collected by
suspended "sediment traps."
"Our findings
show that-given the right conditions-fish fecal pellets can transport
significant amounts of repackaged surface material to depth, and do
so relatively quickly," says Saba.
Those conditions are
likely to occur in places like the western coasts of North and South
America, where ocean currents impinge on continental shelves,
bringing cold, nutrient-rich waters from depth into the sunlit
surface zone.
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