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The Triple Threat: Our Food, Water and Climate Challenges

* By Shiney Varghese <http://www.alternet.org/authors/9258/>, Institute for
Agriculture and Trade Policy <http://www.iatp.org/>. Posted May 14,
2008<http://www.alternet.org/ts/archives/?date%5BF%5D=05&date%5BY%5D=2008&date%5Bd%5D=14&act=Go/>
.*

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Food prices rose 4 percent in the United States last year, the highest rise
since 1990. All over the world food prices are on the rise. At the spring
meetings of the International Monetary Fund and the World Bank finance
ministers wanted to focus the world's attention on food crisis rather than
the credit crisis.

There are many factors contributing to this current crisis, including the
rising price of oil, deregulated agricultural markets, financial
speculation, and biofuels. Another key factor is climate change, which is
affecting crop yield and food production. It is time for us to get serious
about understanding the way climate change affects water resources for food
production and conversely the way agricultural water use is leading to
climate change.

In January, scientists at the Scripps Institution of Oceanography in the
U.S. published an article in the journal *Science* that said what many
climate change experts had already been saying for some time: global warming
is responsible for the extreme changes that we see in the hydrological cycle
in the western U.S. Moreover, the scientists from Scripps found that up to
60 percent of the climate-related trends of river flow, winter air
temperature and snow pack between 1950 and 1999 are human-induced.

While the Scripps scientists analyzed data for the western United States,
similar changes have been happening around the world in the second half of
the twentieth century. The Fourth Assessment Report of the Intergovernmental
Panel on Climate Change (2007) found that "climate and freshwater systems
are interconnected in complex ways and that any change in one of these
systems induces a change in the other."

The IPCC further concluded that the changes in precipitation patterns and
glacier melts are projected to significantly affect water availability for
an entire range of socially valued water uses, including human consumption,
agriculture and energy generation. The most dramatic effect of climate
change is likely to be on agricultural production. The impact is already
manifesting itself in countries such as Australia. The global price of wheat
hit its highest level in decades in December, partly due to Australia's
drought. Irrigated agriculture accounts for almost 70 percent of world water
withdrawals and close to 90 percent of the total consumptive water use (the
portion that is lost to the immediate environment for use). Existing
irrigation and drainage infrastructures have been designed for stable
climate conditions. They are very likely inadequate to cope with extreme
climatic variations in precipitation and reduced water supply reliability
and availability, as well as floods.

On the other hand, since irrigation accounts for such a large percentage of
total water withdrawals, any reduction in irrigation water use (either
through introducing water use efficient technologies or through changing
agroecological practices) will go a long way in coping with climate-related
water stress especially, in water-stressed regions.

While irrigated agriculture accounts for 40 percent of global food
production, the remaining 60 percent of world's food crops are produced by
those practicing rain-fed agriculture. Such agriculture covers more than 80
percent of global agricultural land. In these regions, particularly those
without local water conservation measures, crop productivity depends solely
on sufficient precipitation to meet both evaporative demand and soil
moisture needs. Any variation in precipitation patterns and temperature
increases can affect crop productivity substantially.

The IPCC predicts that in some countries, "yields from rain-fed agriculture
could be reduced by up to 50 percent by 2020." This would most certainly
affect food security in many communities and nations. But it is not only
that climate change-related water stress will affect agriculture. The
converse is also true: current water use patterns and associated practices
contribute to climate change.

It is noteworthy that the two sectors in the world that use the most water,
chemical intensive agriculture and fossil fuel-based energy production, are
also the biggest contributors to global warming, which in turn further
increases water stress in many regions.

For example, agriculture, as it is practiced now, sequesters much less
carbon than it used to because of land use changes. A recent report by
Greenpeace, "Cool Farming: Climate Impacts of Agriculture and Mitigation
Potential," found that "industrial, chemical-intensive agriculture degrades
the soil and destroys the resources that are critical to storing carbon,
such as forests and other vegetation."

There are a number of ways in which national agricultural, trade and energy
policies affect both water resources of a nation and climate change at the
global level. Let us take a brief look at irrigated agriculture. Irrigation
water use increased dramatically in most parts of the world in the second
half of 20th century. This was abetted by the building of massive water
systems including dams, reservoirs, aqueducts, pipelines and canals that
brought water to otherwise water scarce regions.

This growth in irrigated agriculture is part of an unprecedented expansion
of chemical intensive agriculture that was originally sold as a way to feed
the world and also to increase export earnings through commodity-based
trade. The pursuit of export-led growth in agriculture has also been
dependent on intensive use of fossil fuel-based chemical inputs,
contributing greatly to climate change.

In addition, the transport of agricultural commodities around the world and
intensive agricultural practices (such as confined animal feedlots and
indiscriminate fertilizer-use) also contributes to greenhouse gas (GHG)
emissions. According to the World Bank's 2008 report on agriculture,
intensive agriculture directly contributes about half of the global
emissions of two of the most potent non-carbon dioxide GHGs: "Nitrous oxide
emissions from soils (from fertilizer application and manures) and methane
from enteric fermentation in livestock production."

Each account for about one-third of the farm sector's total non-carbon
dioxide emissions and are projected to rise with increased meat consumption
becoming a norm in emerging economies.

Agricultural practices geared towards growing export-oriented monoculture
crops are chemical intensive and have resulted in high levels of pollution
in local water systems. In addition, nitrogen used in fertilizers leaches
into water courses increasing the indirect nitrous oxide emissions
downstream. This model of production has intensified water use, both in
terms of the water going into the growing of the commodities themselves, but
also in terms of inter-basin water transfers.

Protecting our waters in local watersheds and wetlands and using them
judiciously in support of local agricultural systems and livelihood
practices, rather than continuing with the current strategy of promoting
export-oriented, monoculture, industrial, water-guzzling agricultural
systems, is key to reducing the water sector's direct contributions to
climate change. Moreover local practices that conserve and enhance local
water availability to ensure resilience of rain-fed agricultural systems are
necessary as an adaptation mechanism, to meet climate challenges and to help
meet food security goals, two of the biggest challenges for developing
countries today.

It is time to reevaluate our agricultural policies that promote water and
energy intensive agriculture. We will have to make some major changes in our
agriculture systems to address some of the upcoming climate challenges.
Doing so will help us cope with extreme changes in the hydrological cycle
and resultant food and water crises many communities and nations are sure to
face. Effective and sustainable water management in agriculture in support
of healthy food systems needs to be part of the climate solutions.

*Shiney Varghese is a Senior Policy Analyst at the Institute for Agriculture
and Trade Policies*

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