Of course, nature is always in
charge. Our challenge is to learn how to
work with it. In the meantime we now
know that in the long run that the initial conditions are almost irrelevant.
As important though is that the
deliberate development of wetland agriculture needs to understand this and to
try not to fight the inevitable. At best
one can suppress the growth of trees or at least to manage their actual
location. After all that you can
anticipate a cattail bed that can support harvesting many times per year.
Growing fence rows to provide
refugia is certainly indicated providing strip beds of cattails to
harvest. Muskrats are identified as well
as beaver as a likely control problem.
The real problem from a putative
agricultural protocol is to maintain water flow without getting caught up with
a lot of pumps. That may never be quite
possible.
15-year study: When it comes to creating wetlands, Mother Nature is in
charge
by Staff Writers
This is an aerial view of the two experimental wetlands at Ohio State
University Ohio State
University
Fifteen years of studying two experimental wetlands has convinced Bill
Mitsch that turning the reins over to Mother Nature makes the most sense
when it comes to this area of ecological restoration.
Mitsch, an environment and natural resources professor at Ohio State
University, has led the effort to compare the behavior of two experimental
marshes on campus - one that was planted in 1994 with wetland vegetation and
another that was left to colonize plant and animal life
on its own.
The two wetlands now contain nearly the same number of plant species,
and almost 100 more species than existed 15 years ago. When the two marshes
were created, researchers planted 13 common wetland species in one marsh and
left the other to develop naturally. Water from the nearby Olentangy River
The wetlands' general similarities have persisted even after muskrats
spent the winter of 2000-01 destroying most of the plants in both wetlands,
either eating them or using them to build dens. Though the muskrats' favored
cattails dominated the unplanted wetland at the time, bulrush grew back in the
cattails' place as the marshes recovered from the animal damage. Trees also
ring both wetlands, hinting at the possibility that the site could someday be
transformed from a marsh into a forested wetland.
These developments suggest that as time passes, the initial
conditions of the wetlands matter less than how they develop naturally on their
own, Mitsch said.
"Both wetlands are examples of
what we call self-design," he said. "Human beings can be involved in
the beginning, but ultimately the system designs itself according to the laws
of Mother Nature and Father Time." The analysis is published in the March
issue of the journal BioScience.
Mitsch is a staunch proponent of factoring wetlands' contributions to
carbon storage, or sequestration, into worldwide strategies to offset
greenhouse gas emissions. This study and
his other research on freshwater wetlands suggest to Mitsch that wetlands could
provide substantial support in this area.
At the 15-year mark, the unplanted wetland's rate of carbon retention
stood at 266 grams of carbon per square meter per year, compared to 219 grams
in the planted wetland. Mitsch noted that these are considerably higher than
are the carbon sequestration rates estimated at a natural reference wetland
used for comparison: Old Woman Creek near Lake Erie .
Carbon sequestration rates there range from 125 to 160 grams of carbon per
square meter per year.
One significant difference seen between the planted and unplanted
experimental wetlands, however, was their rates of methane emission. Mitsch and
colleagues measured these emissions from 2004 to 2008. The unplanted wetland
emitted about twice as much methane as did the planted wetland, releasing 32
grams and 16 grams of methane per square meter per year, respectively.
"The planted wetland remained a little more diverse in plant
communities, and biodiversity is good. The unplanted wetland appeared to go for
power, in the thermodynamic sense, and had more productivity and more
plants," Mitsch said. "In the end, that's the one that had more
carbon sequestration, but it also had more methane. So you get the yin and the
yang of carbon with the unplanted wetland."
Almost all freshwater wetlands are known to release methane, a
greenhouse gas, into the atmosphere, but Mitsch asserts that wetlands' role as
carbon sinks more than compensates for the methane emissions. Methane oxidizes
in the atmosphere while carbon dioxide does not, tipping the balance of value
for protection against greenhouse gases in favor of wetlands because of their
carbon storage capacity, he said.
These wetlands taught the scientists a number of lessons about wetland
creation despite their small size. The 2 .5-acre marshes are part of Ohio State 's
Wilma H. Schiermeier
Olentangy River
Wetland Research
Park
If the soil is any indication, its adaptation showed that one can
create a wetland anywhere there is a constant source of water. The soil at the
site, former farmland, became hydric - an indicator that a wetland exists -
within just a few years.
The wetlands were a bit of a disappointment in the area of nutrient
retention, which relates to a wetland's work to
purify water.
Phosphorus is problematic in inland freshwater systems, where, in
excess, it can stimulate the growth of algae. The experimental wetlands at Ohio State
For nitrates, which can lead to algae blooms and kill some fish species
in coastal waters such as the Gulf of Mexico ,
the rate of retention in the wetlands decreased from the early years from
almost 40 percent to 25 percent, but now appears to have leveled off.
"The nitrate is a pretty good story, but the phosphorous retention
is a warning that you can't get phosphorous retention from these wetlands over
a really long time. They become saturated," Mitsch said.
He noted that a common discussion in ecology circles these days is a
reference to "ecosystem services," where scientists and policymakers
are asking, 'What can nature do for humans?' In Mitsch's estimation,
wetlands fulfill all expectations: They purify water by removing nitrogen and
phosphorous, regulate the climate by storing carbon, retain flood waters and,
in the case of coastal wetlands, protect coastal areas from hurricane damage,
and enhance biodiversity, in effect serving as natural zoos and botanical
gardens.
In economic terms, that means preservation of wetlands could translate
into less investment needed for the construction of water treatment plants,
flood control reservoirs and carbon sequestration technology, he said.
Something that remains unclear about wetland creation, however, is
whether planting or allowing for natural colonization makes any difference in
the long run. Of the 13 species planted at the beginning of the experiment in
the planted wetland, nine remain there; in the unplanted basin, only two of
those species are growing there at year 15. In the meantime, dozens of new
species grew in each marsh.
"At the end of the day I'm not sure one wetland is more important
than the other. There are positives for both," Mitsch said. "We just
wanted to see for as long as we could what happens over time when you plant one
wetland and don't plant the other. I think they're converging, tending to be
similar."
Co-authors are Li Zhang, Kay Stefanik, Amanda Nahlik, Christopher
Anderson, Blanca Bernal, Maria Hernandez and Keunyea Song, all of the Olentangy River Wetland
Research Park
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