the role of technology in global water problems: the proposed water elevation recovery mission...
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The role of technology in global water problems: The proposed Water Elevation
Recovery missionDennis P. Lettenmaier
Department of Civil and Environmental EngineeringUniversity of Washington
presented at
Water as a Source of Conflict and Cooperation: Exploring the Potential
February 26-27, 2005
Tufts University Medford, Massachusetts
Outline
• Basic facts on global water usage
• Reservoir Impoundments
• TransBoundary Issues
• How a surface water mission would help
A thumbnail sketch of global water issues
Approximately 25,000 people die each year due to floods Drought losses globally have exceeded $300B over the last
decade More than 1.2 billion have inadequate drinking water (poor
quality, insufficient quantity) Twice that many (2.5 billion) lack adequate sanitation
facilities. Approximately 10% of the annual discharge of the world’s
rivers is used consumptively, and several major continental rivers (e.g., Colorado, Nile, Yellow) are dry for at least part of the year
The quality of many of the world’s rivers has been seriously degraded by a combination of pollution, land cover change, dams, and other factors
Many, if not most, of these problems are not amenable to technological solutions – but some are
One such example is the acquisition of data about river discharge, and the storage of water in reservoirs, lakes, and wetlands
Why do we care about streamflow?
• Rivers are the earth’s arteries• Rivers are a primary source of water for human
consumption, food production, transportation, and many other uses
• Riparian corridors (including wetlands) are extraordinarily productive and diverse biologically
• Much of the world’s population lives in flood plains
• Rivers also pose major hazards to human life and well being (due to both floods and droughts)
• Domestic consumptive use (U.S.) is ~200-250 liters/day
• Compare with drinking water requirement (about 5 l/day). U.S. domestic consumption has declined slightly over the last two decades. Much of difference between potable water requirement and use is sanitation, laundry, etc.
• Industrial requirement in developed world is of same order as domestic
• Total water withdrawals are about 6000 km3/yr• Compare with global (land) precip ~150,000
km3/yr (or global runoff ~0.4 x runoff)
The Global Picture● Water resource issues will have large effects on
many of the world’s major decisions in the next 50 years.
● 1 billion people live on less than $1/day.
● More than 1.2 billion have inadequate drinking water (poor quality, insufficient quantity, but still priced beyond the means of the poorest), and twice that many (2.5 billion) lack sanitation facilities.
● Poorly handled: could result in wars and will result in premature deaths, poor quality of life for many, and widespread degradation of aquatic ecosystems.
● Well handled: opportunities for scientific and political creativity, international collaboration, promoting cooperation rather than discord.
Widespread efficiency improvements are possible, in all sectors
• 1930s: 200 tons of water per ton of steel• 1980s: 20-30 tons of water per ton of steel• 2002: 2-3 tons of water per ton of steel• Agricultural water use can drop and yields can increase with better irrigation technology.
• Essentially, industrialized nations have improved their water usage, but what about developing nations?
• And population growth is a water management problem… next 3 slides
Unmet Basic Human Needs for Water
• 1.1 billion people lack access to adequate drinking water (mostly in Africa and Asia).
• 2.4 billion people lack access to adequate sanitation services.
• 2.2 to 5 million die annually from preventable water-related diseases.
–What are the implications for global water management and assessment?
• Ability to globally forecast freshwater availability is critical for population sustainability.
• Water use changes due to population are more significant than climate change impacts.
• Predictions also demonstrate the complications to simple runoff predictions that ignore human water usage (e.g., irrigation).
Vörösmarty, C.J., P. Green, J. Salisbury, and R.B. Lammers, Global water resources: Vulnerability from climate change and population growth, Science, 289, 284-288, 2000.
For 2025, Relative to 1985
Global Reservoir DatabaseGlobal Reservoir DatabaseLocation (lat./lon.), Storage capacity, Area of water surface, Purpose of dam, Year of construction, …
13,382dams,
Global Water System Project
IGBP – IHDP – WCRP - Diversitas
Human modificationof hydrological systems
Regulated Flow
Historic Naturalized Flow
Estimated Range of Naturalized FlowWith 2040’s Warming
Figure 1: mean seasonal hydrographs of the Columbia River prior to (blue) and after the completion of reservoirs that now have storage capacity equal to about one-third of the river’s mean annual flow (red), and the projected range of impacts on naturalized flows predicted to result from a range of global warming scenarios over the next century. Climate change scenarios IPCC Data and Distribution Center, hydrologic simulations courtesy of A. Hamlet, University of Washington.
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Up to1900
1901-1910
1911-1920
1921-1930
1931-1940
1941-1950
1951-1960
1961-1970
1971-1980
1981-1990
1990-1998
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Australia/New Zealand
Africa
Asia
Europe
Central and South America
North America
Reservoir construction has slowed.
All reservoirs larger than 0.1 km3
Brahmaputra River 25-day lead forecasts using experimental ECMWF long-lead precipitation forecasts
Visual courtesy Tony Hollingsworth, ECMWF
• Question: why not just use discharge at upstream gauges in India?
• Answer: Because India won’t release the data (at least in anything close to real-time)
Flooding Issues• Flooding imposes clear dangers,
but the lack of water heights and inundation mapping during the passage of the flood wave limit important hydraulic modeling that would otherwise predict the zones of impact.
• Essentially, can we predict flooding hazards which could be used to understand the consequences of land use, land cover, and climatic changes for a number of globally-significant, inhabited floodplains?
Estimated Costs: $1.9 BillionOver 100 dead in Europe, alone
PraguePrague
KentuckyKentucky
IndiaIndia
ChinaChina
Black SeaBlack Sea
These are the floods from 2002, alone!
From the standpoint of global water issues, what would be the impact of the proposed
WatER mission?• Freely available data on water storage for water
bodies larger than ~1 km• Capability to produce river discharge estimates
for many rivers with width > ~50-100 m• Major implications for the ability to predict floods
and droughts globally• Elimination of “competive advantage” of
upstream countries in trans-boundary rivers• Implications for global markets (especially food)
Possible role and implications of a global surface water mission
• Free and open exchange of global hydrologic data (which presently does not exist)
• Understanding how reservoirs are operated (presently there is no coherent data base for reservoir storage)
• Water and human health (2 billion incidences of waterborne diseases per year globally!)