This is an important discovery along with our understanding of the
limiting nature of iron content in terms of surface water productivity. What it suggests to me is that there is a
need to determine an appropriate methodology that successfully releases iron
into surface waters and we need to be a little clever about it all.
One way may be to mandate a iron rich mineral as plastic fillers so
that bio-degradation is both accelerated and significant in providing the
nutrient. Otherwise, we need to be able
to introduce iron onto surface waters in such a way that they stay suspended
until released. There may be mineral
forms that will meet this need. We need
to look.
Fine grinding will produce such particles of even generally heavy
product. Once put in the water, they can
linger and provide the necessary nutrients.
All this is done by the mining industry as a matter of course. Plenty of minerals have iron in some form or
the other and in time the oxygen will oxidize out. None of them have ever been mined for their
iron or ever will be. The issue is to
make it fine enough to rust out the iron fairly quickly.
Nature does this for us at times by blowing dust storms out to sea. Maybe the simple answer is to load desert sand
on a ship as ballast and proceed to jump it as the ship transits.
Oceanography enters the
Iron Age
Mar 27, 2012
For many years scientists have
known that iron is often associated with organic carbon in sediment but did not
know why. Now researchers from Canada
They estimate that worldwide
19–45 Gigatonnes of organic carbon are locked up in surface marine sediments in
this way. Because reactive iron phases are metastable over long time periods,
the sediments could be an efficient "rusty sink" for organic carbon.
"Burial in sediments is
the only long-term sink of organic carbon on the planet, on geological
timescales," Yves Gélinas of Concordia
University
The most widely accepted
explanation for the tiny proportion of organic carbon preserved, says Gélinas,
is that it's protected by sorption on clay mineral surfaces in the water column
and in sediments.
"Our work shows that
iron oxides are also very important, which is totally new," he added.
"Why does it matter? Simply because iron oxides are not stable in anoxic
[no-oxygen] environments (they form only in oxic settings), while clay minerals
are stable whatever the redox conditions of the system."
The expansion of oceanic
"dead zones" – regions where oxygen levels are too low to sustain
life – could eventually affect this iron complexation mechanism for preserving
organic carbon. According to Gélinas, this will "create a positive
feedback mechanism fuelling greater oxygen consumption" as more organic
matter will be degraded in the water column or at the surface of the sediments,
using additional oxygen and so contributing to the expansion of dead zones.
"Iron has become a very popular
research topic in chemical oceanography since the discovery that it is a
limiting nutrient for primary productivity in large areas of the ocean,"
said Gélinas. "We show for the first time that iron also plays an
important role in organic carbon preservation. We are definitely in the Iron
Age of oceanography."
Gélinas and colleagues from
Concordia University and McGill University tested sediments from around the
world sampled from freshwaters, estuaries, river deltas, continental margins
and the deep sea, using an iron reduction method previously used in soils.
"We now better understand
the controls on organic matter preservation in sediments through its
stabilization by iron complexation," said Gélinas. "[This] means that
we can do a better job building models representing carbon preservation and
cycling in marine environments. It also means better prediction of the
evolution of the organic carbon preservation function in these models as
bottom-water dissolved oxygen concentrations keep decreasing."
Now Gélinas says the team
plans to get a clearer idea of the types of chemical bonds that link iron and
organic matter, and how changes in local redox conditions affect their relative
proportions in sinking particulates and sediments.
"We have recently obtained
Synchrotron X-Ray beam time at the Brookhaven National Light Source Laboratory
(NLSL) in Long Island, US, and acquired a very promising first set of data
showing that our working hypothesis – that iron complexation to organic carbon
plays a much greater than anticipated role in preserving a large fraction of
organic carbon in sediments – is correct," he said. "We have applied
for more beam time at the NSLS and at the Canadian Light Source Synchrotron in Saskatchewan
The team would also like to
estimate the importance of the mechanism in the stabilization of soil organic
carbon.
About the author
Liz Kalaugher is editor
of environmentalresearchweb.
No comments:
Post a Comment