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dam-l [Fwd: Nov. 23rd USGCRP Seminar: "Environmental Water Security: Lessons from the Southwestern U.S., Northwestern Mexico, and the Middle East"]

Hi Dianne,

Thought this might be of use.

Regards,

Jim

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                         U.S. Global Change Research Program Seminar Series


             Environmental Water Security: Lessons from the Southwestern U.S.,

                            Northwestern Mexico, and the Middle East


How has water been used to transform desert regions into productive and
livable environments? What are the current and projected trends in water
use in regions such as the southwestern U.S. and Mexico, and in the Middle
East?  How much water is presently available in the southwestern U.S. and
Mexico, and in the Middle East?  Are the available water resources in these
regions sufficient to sustain anticipated future growth?  If not, what
options are available to these regions?  How might climate change affect
these trends, estimates, and projections?  What are the collective lessons
one might draw from a closer look at water resources in these two otherwise
disparate regions of the world?


                                                       Public Invited

                                 Monday, November 23, 1998, 3:15-4:45 PM
                                   Dirksen Senate Office Bldg., Room G-11
                                                      Washington, DC


                                                    Reception Following




INTRODUCTION

Peter R. Jutro, Senior Scientist, Environmental Protection Agency,
Washington, DC


SPEAKERS

Jason Morrison, Senior Associate, Pacific Institute for Studies in
Development, Environment, and Security, Oakland, CA

Aaron T. Wolf, Department of Geosciences, Oregon State University,
Corvallis, OR



           Water Scarcity and Environmental Security in the Southwestern US and
                                               Northwestern Mexico


Spanning 1,400 miles and eventually running through Mexico to the Sea of
Cortez, the Colorado River is the lifeblood for the arid southwestern
United States and northwestern Mexico.  Current management and use of water
resources in the Colorado River basin serve as a good illustration of the
connections among increasing scarcity, legal conflicts, and the
unsustainable use of water resources.  In particular, social problems
associated with the overallocation and misallocation of total water
resources, and substantial threats to significant ecological resources such
as the Colorado River delta, are all reaching critical levels as demands
for the limited resources of the basin are increasing.

Of the top five fastest growing states in the United States, four are in
the Colorado River Basin.  Likewise, population in the northern Mexico
states of Sonora and Baja California has been, and is expected to continue,
growing at a rate of 5 percent per year.  Increases in population and in
urban water demands are projected to place even greater stress on an
agricultural economy already suffering from the rapid conversion of open
space to urban development.  Long-term groundwater overdraft, while not yet
a significant problem in the upper basin, occurs on an annual basis in all
three of the lower basin states and also in Mexico's Mexicali Valley.
Compounding the pressure on the already scarce resource are unfulfilled
American Indian water claims and growing demands for giving a higher
priority to fisheries and habitat protection in order to restore aquatic
systems of the Colorado River and its estuary.

Growth in water demand has been very rapid.  In 1988, Nevada used less than
130,000 acre-feet (af=one acre of water one foot deep) of its 300,000
acre-foot Colorado River entitlement.  By 1995, its use of the river's
water grew to 225,000 af/year, and today, even with the inclusion of
ambitious water conservation goals, water managers predict the state will
use its full entitlement before 2025.  The population of Las Vegas grew by
over 26 percent from 1990 to 1994, and the total population of southern
Nevada is expected to more than double its 1990 population of 800,000 by
the year 2020.  The state of Arizona and the northwestern region of Mexico
are both expected to grow by 90 percent over the same period.

As of 1990, more than 1.2 maf (one million acre feet=one million acres of
water one foot deep) of groundwater were being overdrafted on an annual
basis in the lower Colorado River basin and Mexico.  Historically, average
groundwater withdrawals in Arizona have exceeded recharge by approximately
2 maf/year.  However, due largely to Colorado River water delivered through
the Central Arizona Project, current groundwater overdraft has been reduced
to less than 1 maf/year.  As of five years ago, almost 15 percent of
Arizona's water supply consisted of overdrafted groundwater.  Despite
Arizona's "safe yield" goals, current programs and planned measures will
alleviate only a portion of the groundwater overdraft; long-term
projections suggest annual overpumping in excess of 500,000 af/year in
2025.

Moreover, unquantified Indian claims in the state of Arizona alone have
been estimated to be as high as 3 maf, which is more than the state's
entire Colorado River entitlement of 2.8 maf.


Dividing and Developing the Colorado River

Today, the Colorado River supplies water to nearly 30 million people and
irrigates more than 3.7 million acres of farmland in the U.S. and Mexico.
Controlled by some 29 dams, the Colorado River ranks among the most heavily
plumbed water systems in the world.  Except for unusually high flood years,
virtually the entire flow of the river is now captured and used -- and has
been since the early sixties, when Glen Canyon Dam was completed.

A fundamental problem in the Colorado River basin is that the long-term
planned use of the river's water exceeds the reliable available supply.
Because total legal entitlements to the river's water are greater than the
river's average annual flow, the river has been deemed "over-apportioned."
One of the principal assumptions at the time the 1922 Colorado River
Compact was signed by water users of the basin was that the long-term
average flow of the river was close to 18 maf/year measured at Lee Ferry,
the official point dividing the upper and the lower portions of the basin.
The U.S. Bureau of Reclamation currently estimates the average flow at Lee
Ferry to be approximately 15 maf/year.  Despite the fact that the river's
flows were grossly overestimated, subsequent laws and decrees have been
based upon the original Compact apportionments.

Further, when the waters of the river were divided over 70 years ago, no
water was dedicated to maintain healthy aquatic ecosystems.  Recreation and
ecosystem health are not explicitly recognized in the current management
approaches.  In fact, until quite recently, environmental needs such as
instream flows have been met with unused entitlements.  In other words,
environmental water requirements such as the sustainability needs of the
Colorado River Delta had been relegated to living off of "borrowed" water.


Crisis and the Seeds of Change

There is not enough water in the system under current laws and management
regimes to satisfy all future human demands and to protect the river's
ecological functions.  While upper basin states remain far from using their
full legal entitlement to the river's water, in 1990, for the first time,
the lower U.S. portion of the basin used its full 7.5 maf entitlement.
Reaching this threshold has provoked a general rethinking of management
strategies (i.e., off-stream groundwater storage of surplus flows, the
simulation of more natural flow regimes, and voluntary transfers of water)
to exercise and promote more efficient use of water and to redistribute
water toward higher-valued activities.

Deeply ingrained attitudes and vested interests still represent formidable
obstacles to changing water use and management practices.  Continuing down
the current path of inefficient and highly subsidized agricultural water
use, escalating urban demands, and neglect of ecosystems, Native American
communities, and future generations, is a recipe for conflict and
ecological decline.


Conclusions

The massive and long-term overdraft of groundwater resources in nearly
every region in the lower basin is not sustainable and reduces options for
future generations.

Considerably more thought and attention might be directed at integrating
the planning and management efforts of the various entities in the region.
Only cooperative efforts involving all parties are likely to remedy the
problems of the Colorado River.  Land-use planning could be more effective
if integrated with water planning, and vice versa.

The issues of restoring and protecting freshwater ecosystems in the basin
will have to be dealt with explicitly.  Failure to do so will likely result
in continued degradation of the environmental health of the Colorado River
basin.  Any successful ecosystem restoration program for the delta will
likely require a formal international agreement.

The unresolved issue of Indian tribes' water rights claims requires
resolution.


                                         Water Security in the Middle East


More than half of the total land surface of the planet is drained by some
261 international rivers, and internationally shared aquifers abound.
Water has been a cause of political tensions between Arabs and Israelis;
Indians and Bangladeshis; Americans and Mexicans; and all ten riparian
states of the Nile River.  Water is the only scarce resource for which
there is no substitute, over which there is poorly-developed international
law, and the need for which is overwhelming, constant, and immediate.

Accounts of conflict related to water indicate that only seven minor
skirmishes have occurred in this century, and that no war has yet been
fought over water.  In contrast, 145 water-related treaties were signed in
the same period.  Shared interests along a waterway seem to consistently
outweigh water's conflict-inducing characteristics.  Furthermore, once
cooperative water regimes are established through treaties, they turn out
to be impressively resilient over time, even between otherwise hostile
riparians, and even as conflict is waged over other issues.  These patterns
suggest that international water is a resource whose characteristics tend
to induce cooperation, and incite violence only in the exception.

The history of hydropolitics along the rivers of the Middle East
exemplifies both the worst and the best of relations over international
water.  All of the Jordan River riparian countries and territories riparian
to the Jordan River - Israel, Syria, Jordan, and the Palestine Authority -
are currently using between 95% and more than 100% of their annual
renewable freshwater supply.  In recent dry years, water consumption has
routinely exceeded annual supply, the difference usually being made up
through overdraft of fragile groundwater systems.  By 2020, shortages will
be the norm.  Projected water requirements for the year 2020 are 1.62 maf
annually for Israel, approximately 130% of current renewable supplies, 0.81
maf, or 120% of current supplies, for Jordan, and 0.25 maf, or 150% of
current supplies, for the Palestinians on the West Bank and Gaza.
Making the resolution of tensions more difficult is the fact that intense
and fluctuating geopolitical forces have crafted political boundaries in
direct contradiction to the natural boundaries of the watersheds of the
region.

Water-related tensions, for example, involved the borders of the British and
French Mandates, later the modern entities of Israel, Jordan, Lebanon, Syria,
and the Palestine Authority.  As each of these entities developed their water
resources unilaterally, dispute became inevitable - every state or
territory in the Jordan watershed has at least some of its water sources in a
different, and occasionally hostile, state or territory.  Exchanges of fire
actually
broke out over water between Israel and Syria in the mid-1950's and 1960's.
The problems were only exacerbated with the 1967 war.

The West Bank overlies three major aquifers, two of which Israel has been
tapping into from its side of the Green Line since 1955.  In the years of
Israeli occupation, a growing West Bank and Gaza population, along with
burgeoning Jewish settlements, has increased the burden on the limited
groundwater supply, resulting in an exacerbation of already tense political
relations.  Palestinians have objected strenuously to Israeli control of
local water resources and to settlement development, which they see as
being at their territorial and hydrologic expense.  Israeli authorities
view hydrologic control in the West Bank as defensive.  With about 30% of
Israeli water originating on the West Bank, the Israelis perceive the
necessity to limit groundwater exploitation in these territories in order
to protect the resources themselves, and their wells from saltwater
intrusion.  It is no wonder that water was the last and most contentious
issue negotiated in the Jordan-Israel Treaty of Peace of 1994, or that the
question of water rights between Israel and the Palestinians has been
postponed until final status talks, along with the most intricate and
politically sensitive issues of Jerusalem and statehood.

Nevertheless, while shared water resources have led to, and occasionally
crossed, the brink of armed conflict, they have also been a catalyst for
cooperation between otherwise hostile neighbors, albeit rarely and
secretively.  For example, despite a growing literature which suggests that
Israel-Arab warfare has had a "hydrostrategic" component, the evidence
suggests that water resources were not at all factors for strategic
planning in the hostilities of 1948, 1967, 1978, or 1982.  The decision to
go to war, and strategic decisions made during the fighting including which
territory was necessary to capture, were apparently not influenced by water
scarcity or the location of water resources.  Moreover, while the questions
of water allocations and rights have been among the most difficult
components in the Arab-Israeli peace talks, and despite the quantity of
studies identifying hydrostrategic territory and advising its retention, no
territory to date has been retained simply because of the location of
water.  Solutions in each case have focused on creative joint management of
the resource, rather than insistence on sovereignty.


                                                           Biographies

Jason Morrison is a Senior Associate of the Pacific Institute for Studies
in Development, Environment, and Security, a non-profit, non-partisan
research center based in Oakland, California.  He is a leading expert on
the sustainable management of freshwater resources and water planning in
California and the southwestern U.S.  His current research includes work on
restoration of the Salton Sea in California and binational water management
in the Colorado River border region.

Mr. Morrison has published widely in scholarly and popular publications,
and is the lead author of a 1996 United Nations report entitled: The
Sustainable Use of Water in the Lower Colorado River  Basin.  He is also
co-author of the Colorado River Basin analysis in the soon-to-be-released
report, Transboundary Freshwater Resources of North America, sponsored by
the Commission for Environmental Cooperation.  In addition to working on
issues relating to western water policy, Mr. Morrison heads the Pacific
Institute's Economic Globalization, and the Environment Program..  He is
currently analyzing the public policy implications of voluntary
international standards, focusing on the environmental management standards
-- ISO 14000.

Mr. Morrison is presently a member of the US Technical Advisory Group to
ISO Technical Committee 207, as well as a US "expert" delegate to
Subcommittee 3 (Ecolabeling), and to Subcommittee 5 (Life Cycle
Assessment).  He is a participant of the Multi-State Working Group on ISO
14001 Environmental Management Systems, and a founding member of the NGO
Working Group on ISO 14000.

Mr. Morrison holds a M. S. degree from Boston University's Center for
Energy and Environmental Studies and a B. A. degree in Philosophy from the
University of California, San Diego.  In 1994, Mr. Morrison was a fellow
with the Americans and World Affairs Fellowship Program  in Berkeley,
California.


Aaron T. Wolf is an assistant professor of geography in the Department of
Geosciences at Oregon State University in Corvallis, Oregon.  His recent
research focuses on issues relating international water resources to
political conflict and cooperation, where combining environmental science
with dispute resolution theory and practice have been particularly
appropriate.  He has acted as consultant to the US Department of State, the
US Agency for International Development, and the World Bank on various
aspects of international water resources and dispute resolution.  He has
been involved in developing strategies for resolving water-related aspects
of the Arab-Israeli conflict, including co-authoring a State Department
reference text, and participating in both official and "track II" meetings
between co-riparians.  He is author of Hydropolitics Along the Jordan
River: The Impact of Scarce Water Resources on the Arab-Israeli Conflict,
(United Nations University Press, 1995), and co-author of Core and
Periphery: A Comprehensive Approach to Middle Eastern Water, (Oxford
University Press, 1997).

Dr. Wolf coordinates the Transboundary Freshwater Dispute Database, which
includes a computer database of 150 water-related treaties, negotiating
notes and background material on fourteen case-studies of conflict
resolution, news files on cases of acute water-related conflict, and
assessments of indigenous/traditional methods of water conflict resolution.
He is also on the advisory councils of UNESCO's International Hydrological
Program, and the ADC New Millennium World Water Tribunal.
Dr. Wolf is a member of the Association of American Geographers, the
American Water Resources Association, the International Water Resources
Association, and the International Association for Impact Assessment.  He
is an associate editor of the Journal of the American Water Resources
Association, Water International, and World Water Policy.

Dr. Wolf has an M.S. degree in water resources management (emphasizing
hydrogeology) and a Ph.D. in environmental policy analysis (emphasizing
dispute resolution) from the University of Wisconsin, Madison.



The Next Seminar is scheduled for Tuesday, December 8, 1998


Tentative Topic: Changes in Carbon Sources and Sinks: The Outlook for
                                   Climate Change in the Future.


For more information please contact:

Anthony D. Socci, Ph.D., U.S. Global Change Research Program Office, 400
Virginia Ave. SW, Suite 750, Washington, DC 20024; Telephone: (202)
314-2235; Fax: (202) 488-8681 E-Mail: TSOCCI@USGCRP.GOV.

Additional information on the U.S. Global Change Research Program (USGCRP)
and this Seminar Series is available on the USGCRP Home Page at:
http://www.usgcrp.gov.  A complete archive of seminar summaries can also be
found at this site.  Normally these seminars are held on the second Monday
of each month.

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