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Organic
Farming
-vs-
CO2
Fast
Facts
If only 10,000
medium sized farms in the U.S. converted
to organic production, they would
store so much carbon in the soil that it would
be equivalent to taking 1,174,400
cars off the road, or reducing car
miles driven by 14.62 billion miles.
Converting
the U.S.’s 160
million corn and soybean acres to organic production
would sequester enough carbon to satisfy
73 percent of the Kyoto targets
for CO2 reduction in the
U.S.
U.S. agriculture as currently practiced emits
a total of 1.5 trillion pounds of CO2
annually into the atmosphere. Converting
all U.S. cropland to organic would
not only wipe
out agriculture's massive emission problem.
By eliminating energy-costly chemical fertilizers,
it would actually
give us a net increase in soil carbon of 734 billion
pounds.
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About
this series:
As some of you may know, The Rodale Institute®,
which publishes The New Farm®,
is home to the longest running field trials in
the country comparing organic and conventional
systems of farming called The
Rodale Institute Farming Systems Trial® (FST).
The data from that 23 years of research is a real
treasure trove of insight into the economic, ecological
and agronomic benefits of organic farming.
In addition to the long-running FST, we have
a variety of other research in progress at The
Institute. David Douds has been studying soil
fungi here at The Institute’s research farm
for 15 years. (Go to Cultivating
diversity underground for better yields above
for more on David's research.) We’re engaged
in no-till research, weed research, compost tea
research, composting research, water quality research,
and much more.
Until now, much of the light we’re generating
here on our research farm has been hidden under
the proverbial barrel, but we’re taking
off the barrel and busting it up for firewood.
We’re going let the light of the amazing
research being done here shine on farmers, consumers
and environmental activities.
Over the next year we’ll be running a series
of stories, about one a month, on the significance
of our research ... and its practical applications.
That includes a few stories on equipment construction—a
front-mounted roller for no-till, and a compost
turner converted from a junked 18-wheeler.
So sit tight, and be prepared to be amazed.
Enjoy,
Chris Hill
Executive
Editor
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The Rodale Institute®
announces a partnership with Pennsylvania's Department of
Environmental Protection and Department of Agriculture to
explore ways these findings can benefit farmers and the environment.
One possibility: carbon credits could be in your agricultural
future.
OCTOBER 10, 2003: Kutztown, PA Discussions
of global warming in the popular press seldom fail to note
its potentially disastrous consequences for agriculture as
we know it: more extreme and unpredictable weather, coastal
flooding, even the loss of pollen viability for some crop
species at higher temperatures all threaten to push the usual
unpredictability of farming into the realm of the completely
unworkable. But while these threats are indeed grave--and
many farmers believe they are witnessing such effects already--researchers
at The Rodale Institute® have been looking at the problem
from the other direction: what impact do agricultural practices
have on global warming?
On October 10, The Rodale Institute® (TRI), the Pennsylvania
Department of Environmental Protection (PDEP), and the Pennsylvania
Department of Agriculture (PDA) signed a memorandum of understanding
designed to help answer that question. Twenty-three years
of ongoing research at The Rodale Institute Experimental Farm
already provides strong evidence that organic farming helps
combat global warming by capturing atmospheric carbon dioxide
and incorporating it into the soil, whereas conventional farming
exacerbates the greenhouse effect by producing a net release
of carbon into the atmosphere.
The key lies in the handling of organic matter (OM): because
soil organic matter is primarily carbon, increases in soil
OM levels will be directly correlated with carbon sequestration.
While conventional farming typically depletes soil OM, organic
farming builds it through the use of composted animal manures
and cover crops. Now, in a unique new partnership, PDEP, PDA
and The Rodale Institute are interested in working together
to see how organic farming practices can be used to help Pennsylvania--and
the world--curb greenhouse gases.
In recent months, TRI Research Manager Paul Hepperly and
President John Haberern have drafted a White Paper summarizing
TRI's research findings and their relevance to global climate
change. The formal agreement, signed last Friday, will provide
a platform for further research into the environmental and
economic benefits of organic and sustainable farming. By coordinating
with PDEP and PDA, Haberern explains, "we can undertake
a systematic review of all the existing data on this issue,
and examine how the process could be accelerated."
What they learn could be used in reclaiming strip-mined areas
of Pennsylvania or in processing waste materials, as well
as in improving the state's farming practices. As a regional
leader in the agricultural management community and a global
leader in sustainable agriculture, TRI also hopes to play
an active role within the Northeast Greenhouse Gas Region
recently designated by the US Department of Energy.
What we know already:
Over
23 years, there’s been a 15 to 28% increase in soil
carbon in organic systems, with virtually no increase in
non-organic systems.
The data demonstrating that organic farming practices can
reduce atmospheric carbon levels come from TRI's longest-running
field study, The Rodale Institute Farming Systems Trial®
(FST). Launched in 1981, the FST is a 12-acre, side-by-side
experiment comparing three agricultural management systems:
one conventional, one legume-based organic, and one manure-based
organic. In 23 years of continuous recordkeeping, the FST's
two organic systems have shown an increase in soil carbon
of 15-28%, while the conventional system has shown no statistically
significant increase. For the organic systems that translates
into more than 1000 lbs of captured C (or about 3670 lbs of
CO2) per acre-foot per year—and
that’s not even counting the reductions in CO2
emissions represented by the organic systems' lower energetic
requirements. A comparative analysis of FST energy inputs,
conducted by Dr. David Pimentel of Cornell University, found
that organic farming systems use just 63% of the energy required
by conventional farming systems, largely because of the massive
amounts of energy required to synthesize nitrogen fertilizer.
"Results like these are a bright spot within the otherwise
dreary picture of global climate change research," notes
Daniel Desmond, Director of the Office of Pollution Control
at PDEP. Organic farmers "are the only group or philosophy
that looks at carbon as a resource rather than carbon as a
waste product."
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So just
how much carbon dioxide can
organic farming take out of the air each year?
Think of it in terms of the equivalent # of cars
that would be taken off the road each year by
farmers converting to organic production. Organic
farms sequester as much as 3,670 pounds of carbon
per acre-foot each year. A typical passenger car,
according to the EPA, emits 10,000 pounds of carbon
dioxide a year (traveling an average of 12,500
miles per year). Here's how many cars farms can
take off the road by transitioning to organic:
AND,
if all 160 million acres of conventinal corn and
soybeans in the U.S. were converted
to organic production, that could translate to:
- 58.7 million cars off the road! (25% of the
national total)
- That's 733,750,000,000 car miles not driven...or
116,666,666 round trips from New York City to
Los Angeles not taken!
FINALLY,
if all 431 million acres of U.S. cropland
were converted to organic:
- 158,177,000 cars would be taken off the road
(over half of the national total)
- 1.98 trillion car miles not driven.
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Global climate change and the carbon cycle
While a handful of political conservatives continue to dispute
the seriousness of global warming and the necessity for a
concerted international effort to mitigate its effects, the
vast majority of scientists have concluded that global climate
change is a reality:
- Atmospheric carbon dioxide levels--the major factor in
the greenhouse effect--are now twice as high as they were
during the last Ice Age, have risen from 280 parts per million
(ppm) to 365 ppm in the last two centuries alone, and are
now increasing at a rate of 1.3 ppm per year.
- Consumption of remaining fossil fuel reserves would boost
CO2 by a factor of four to eight.
- Other greenhouses gases, including methane (CH4),
nitrous oxide (N2O), and chlorofluorocarbons
(CFCs), have also proliferated and would take decades to
stabilize even if emissions were magically cut tomorrow.
- Global mean surface temperatures have climbed 0.6ºC
since the 1850s and are expected to rise 1.5 - 5.0ºC
by 2100. Paleoclimatic evidence indicates that the 1990s
were the warmest decade since the year 1000.
In their efforts to understand and to address the effects
of global warming, scientists are developing an increasingly
sophisticated picture of the global carbon cycle. Total carbon
storage provided by different parts of the global system--terrestrial
vegetation, the surface ocean, the deep ocean--have been quantified,
as have the annual fluxes of carbon among them. CO2
emissions from human and animal activities now stand at about
8.9 billion U.S. tons per year, while net atmospheric CO2
accumulation is 3.5 billion US tons. In other words, 40% of
annual human-induced carbon emissions contribute to build-up,
while the remaining 60% are absorbed by the oceans and terrestrial
plants.
Reforestation not enough to handle rise
in greenhouse gas emissions. Farmlands are a better carbon
“sink.”
Proposals to expand natural carbon sinks as a partial remedy
for global warming initially focused on reforestation. Changes
in land use, including the loss of forests to tillage and
grazing, were known to be a major contributor to the greenhouse
effect--as recently as the 1970s, total accumulated C emissions
from land-use change exceeded total emissions from the burning
of fossil fuels--and it was thought that escalating fossil
fuel consumption could be balanced by vast forests breathing
in all that CO2.
Data like those emerging from the Farming Systems Trial,
however, are revising that image: It may be that the soil
itself makes more of a difference than what's growing in it.
On a global scale, soils hold more than twice as much carbon
(an estimated 1.74 trillion U.S. tons) as does terrestrial
vegetation (672 billion U.S. tons), and practices like reduced
tillage, the use of cover crops, and incorporation of crop
residues can dramatically alter the C storage of arable lands.
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How to
get from a net loss of soil carbon to a net gain
in one easy step!
Dr. David Pimentel, Cornell University’s
specialist in analyzing energy expenditure in
agricultural systems, calculates that U.S. agriculture
currently emits about 925 billion pounds of carbon
dioxide each year from crop and livestock production.
So, what would happen if all those U.S. acres
converted to organic production?
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"Agriculture and forestry are a very potent sink--they
will make the emissions problem easier to get a handle on,"
explains Haberern. "Especially if you do the agriculture
right. If you practice conventional agriculture, then any
low to non-existent C gain you get will have to have subtracted
from it the C emissions created by conventional agricultural
methods. With organic farming it can be pure gain. Using bio-diesel
[for tractor power], you don't need to use any fossil fuels
at all."
Organic farming for carbon capture is also compatible with
other environmental and social goals such as reducing erosion,
minimizing impact on native ecosystems, and improving farmer
livelihoods. Compared to forests, moreover, agricultural soils
may be a more secure sink for atmospheric carbon, since they
are not vulnerable to logging and wildfire.
Although it is well established that sustainable and organic
farming methods sequester atmospheric carbon, researchers
have yet to flesh out the precise mechanisms by which this
takes place. In the FST, soil carbon levels increased more
in the manure-based organic system than in the legume-based
organic system, presumably because of the incorporation of
manures, but the study also showed that soil carbon depends
on more than just total C additions to the system--cropping
system diversity or carbon-to-nitrogen ratios of inputs may
have an effect. "We believe that the differences in decay
rates [of soil organic matter] have a lot to do with it,"
says Hepperly, since "soluble nitrogen fertilizer accelerates
decomposition" in the conventional system.
On the other hand, the work of another Rodale research collaborator,
Dr. David Douds of the Agricultural Research Service, suggests
that healthy mycorrhizal fungi populations in the organic
systems slow down the decomposition of organic matter. (Visit
Cultivating
diversity underground for better yields above for more
on Douds' mycorrhizal research.) All of these factors lead
Hepperly to conclude that "it's crucial to look at the
biological nature of the soil carbon system," rather
than just to consider it as a geochemical process.
Should organic farmers get 'carbon credits'?
A further goal of the partnership between The Rodale Institute,
the PA Department of Agriculture and the PA Department of
Environmental Protection is to explore policy mechanisms by
which farmers and landowners could quantify the carbon sequestered
on their properties and receive a payment from the state or
federal government for ecosystem services provided, or even
participate in emerging 'carbon-trading' markets around the
world. Although the development of carbon-trading markets
in the US was put on hold by the Bush administration's decision,
in 2001, to pull out of the Kyoto Protocol (citing projected
deleterious effects on the struggling US economy), such markets
are rapidly expanding in the European Union and elsewhere.
(See, for example, co2e.com,
a greenhouse gas brokerage firm based in London.)
"The Kyoto Protocol [the 1997 global agreement to reduce
greenhouse gases] talks about agriculture and forestry as
carbon sinks, but fails to distinguish between the different
effects of different types of agriculture," notes Daniel
Desmond of the PA Department of Environmental Protection.
In fact, the whole business of credit for carbon-sequestration
activities under the Kyoto accord is problematic, because
of the lack in 1997 of good carbon inventory data that could
be factored into the nation-by-nation emissions-reduction
targets.
Nevertheless, although sequestration in agricultural soils
can vary by climate and by soil type, multiplying 3,670 pounds
of captured CO2 per acre across the
160 million acres planted to corn and soybeans in the US yields
a potential CO2 capture on the order
of 293 million tons per year, or as much as three-quarters
of the reductions required if the US were to adhere to its
Kyoto targets. (Total U.S. cropland is 431 million acres.)
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Organic
farming -vs- the Kyoto targets
In 1997 the U.S. agreed to reduce 1990 levels
of CO2 by seven percent.
So here's a question: How far would converting
U.S. cropland to organic take us toward satisfying
those Kyoto goals? Let's do the math:
Converting
160 million acres of corn
and soyean to organic results in
293
million tons of CO2 stored
in soil
Kyoto target:
400
million ton reduction in CO2
Percentage of Kyoto goal
that would be
satisfied by converting to organic:
73
PERCENT!
NOTE:
This doesn't even take into consideration the
drastically reduced energy expenditure and CO2
emissions of organic farming compared with using
chemical fertilizers.
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Thinking globally, the British Royal Society has estimated
potential CO2 sequestration on the
world's 2.5 billion acres of agricultural soils at 6.1 to
10.1 billion U.S. tons per year for the next 50 years. Another
estimate puts the total amount of CO2
that could be captured in developing countries at 1.7 billion
U.S. tons over the next decade. In short, carbon sequestration
via adoption of organic agriculture could have a substantial
impact on global warming.
Still, carbon sequestration by organic farming, like carbon
capture through reforestation, is a short-term or 'bridge'
solution, a way of buying time for more fundamental changes.
Ultimately, global climate change can only be fully addressed
through rationalization of energy policies, reductions in
fossil fuel consumption, and improvements in emissions-control
technologies. Among the possible short- to medium-term solutions,
however, organic farming has a lot going for it. "There
are a number of 'Star Wars'-like solutions being proposed"
for carbon and carbon dioxide capture, observes Hepperly,
including pumping CO2 deep into the
ocean or underground--in July of this year the US Department
of Energy announced that drilling had begun on a 10,000-ft
'well' to funnel CO2 deep beneath West
Virginia.
Compared to expensive, experimental, high-technology projects
like these, global transitioning to organic farming looks
cheap and easy. "It's a no-brainer," Hepperly concludes.
"Organic farming is not a technological fix, not an untried
experiment that could have its own unforeseen consequences."
Instead, it's a step toward solving global warming that brings
with it a wealth of other environmental benefits.  |
