Research Highlights

Global Climate Effects on Projected Water Needs

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Predicting and adapting to the long-term effects of global climate change on U.S. water resources in the 21st century is a monumental challenge. But the Water Resource Adaptation Program (WRAP), developed by a water research team in EPA’s National Risk Management Research Laboratory, provides broad-based computer database and prediction methodologies while adaptation methodologies are being developed to take on the challenge. WRAP’s research addresses both natural and human-made climate effects on the sustainability of U.S. water resources in meeting long-term growth and economic development.

While climate changes may have a global reach, human demands for safe and plentiful water are always issue driven and region specific. Based on this, WRAP’s research focuses on the projection and resolution of local or regional water issues. Some examples include the:

• Potential reuse of wastewater in the drought-prone Great Plains states
• Remediation of saltwater intrusion into Florida and other coastal regions
• Mitigation of flash floods and storm water effects throughout the lower Mississippi basin

WRAP is carrying out a national and regional assessment to characterize impacts on water resources, and on drinking water, storm water, and wastewater infrastructure to provide a framework for adaptation studies. The program is collaborating with researchers from universities and water utilities, state and regional agencies, and other stakeholders.

Background

The scientific community recognizes climate change as one of the most significant challenges ever faced and predictions of climate effects on water sustainability are necessarily complex. The breadth of the WRAP program reflects that complexity; however, the program’s two fundamental goals are clear:

• To identify historic variations in climate in order to adapt to natural effects on future water supplies
• To determine current human effects on climate in order to mitigate their effects on future water supplies

To reach these goals, WRAP’s research has two major components: to quantify hydroclimatic variations and to identify which are natural and which are human made.

In the United States, the history of natural climate variations can be derived from computer models, as well as from weather records of precipitation, temperature, and other indicators gathered from more than a thousand observation stations over several hundred years. WRAP model analyses of these natural climatic events over decades, or even millennia, can help predict future sustainability of water resources.

Human demographic and economic effects on climate and water supplies leave their own footprint for statistical assessment. WRAP’s research factors into its projections such human-made inputs as land use, population growth, urbanization, and economic development, thereby providing information for planning and management of water infrastructure, emerging contaminants in alternative water sources, and water needs in alternative energy production.

The second component of WRAP’s research is the development of adaptive engineering and technologies. This research seeks effective measures for reducing the negative impacts of climate changes. Using the findings from the first research component, NRMRL scientists and engineers are exploring ways to:

• Improve water quality under extreme precipitation conditions
• Explore alternative water resources to combat drought and meet the water needs of alternative energy production
• Reduce the impact of salt water intrusions in coastal areas
• Ensure sustainable water supplies in new climate conditions

Overall, WRAP recognizes that climatic and water systems are two separate but closely coupled physical systems. The program takes a holistic approach that integrates natural and human effects on the two systems to help answer potential challenges related to EPA’s role in providing standards for sustainable water supplies in the 21st century. A sampling:

How will future precipitation patterns affect engineering designs for wastewater collection, drinking water source systems, and combined sewer overflows?

What regions under increasing water stress may require alternative water sources (such as substantial reuse of wastewater) and how will Clean Water Act regulations be adapted to alternative water supply management?

What are the effects of saltwater intrusion in coastal zones on ground water sources of drinking water under probable climate-change scenarios and what corresponding treatment actions may be required?

What advanced water management concepts (such as decentralization of treatment and delivery systems) may be needed to support existing and aging water infrastructure systems?

Natural climate change, human population growth, and economic development have altered, and will continue to alter, the delicate balance between water sources and water demand around the globe. In the United States, the WRAP program and its interdisciplinary team are working to address the overarching scientific questions and find practical solutions to meeting the challenge of sustainable water supplies for the future.

Contact

Jane Ice, NRMRL Office of Public Affairs (513) 569-7311

New NRMRL Publications

Bowker, G.E., R.W. Baldauf, V. Isakov, et al. (2007). “The Effects of Roadside Structures on the Transport and Dispersion of Ultrafine Particles From Highways.” Atmospheric Environment , 41, 37: 8128–8139.

Eighmy, T.T., J.C. Spear, J. Case, et al. (2007). “Microfracture Surface Geochemistry and Adherent Microbial Population Metabolism in TCE-Contaminated Competent Bedrock.” Geomicrobiology Journal, 24, 3:307–330. Abstract

Foote, M., H. Joyce, S. Nordwick, and D.R. Bless. (2007). “Passive Treatment of Acid Rock Drainage From a Subsurface Mine.” Chapter 9 in Understanding and Responding to Hazardous Substances at Mine Sites in the Western U.S.; Reviews in Engineering Geology , XVII, p. 153–161.

Mayer, P.M., S.K. Reynolds, M.E. McCutchen, and T.J. Canfield. (2007). “Meta-Analysis of Nitrogen Removal in Riparian Buffers.” Journal of Environmental Quality, 36, 4: 1172–1180. Abstract

Nadagouda, M.N. and R.S. Varma. (2001). “Green Approach to Bulk and Template-Free Synthesis of Thermally Stable Reduced Polyaniline Nanofibers for Capacitor Applications.” Green Chemistry, 9, 6: 632–637. Abstract

Nadagouda, M.N. and R.S. Varma. (2007). “Microwave-Assisted Synthesis of Crosslinked Poly(vinyalcohol) Nanacomposites Comprising Single-Walled Carbon Nanotubes, Multi-Walled Carbon Nanotubes, and Buckminsterfullerene.” Macromolecular Rapid Communications , 28, 7: 842–847.

Nadagouda, M.N. and R.S. Varma. (2007). “Synthesis of Thermally Stable Carboxymethyl Cellulose/Metal Bioodegradable Nanocomposites for Potential Biological Applications.” American Chemical Society , 8, 9: 2762–2767.

Polshettiwar, V. and R.S. Varma. (2007). “Biginelli Reaction in Aqueous Medium: A Greener and Sustainable Approach to Substituted 3,4-dihydropyrimidin-2(1H)-Ones.” Tetrahedron Letters , 48, 41: 7343–7346.

Polshettiwar, V. and R.S. Varma. (2007). “Tandem Bis-Aldol Reaction of Ketones: A Facile One-Pot Synthesis of 1,3-Dioxanes in Aqueous Medium.” Journal of Organic Chemistry, 72, 19: 7420–7422. Abstract

Princiotta, F.T. (2007). “Global Climate Change—The Technology Challenge.” In: Proceedings Air Pollution 2007, Fifteenth International Conference on Modelling, Monitoring, and Management of Air Pollution , Algarve, Portugal, April 23–25.

Su, C. and R. W. Puls. (2007).“Removal of Added Nitrate in the Single, Binary, and Ternary Systems of Cotton Burr Compost, Zerovalent Iron and Sediment: Implications for Groundwater Nitrate Remediation Using Permeable Reactive Barriers.” Chemosphere, 67, 8: 1653–1662. Abstract

Varma, R.S. and V. Polshettiwar. (2007). “Polystyrene Sulfonic Acid Catalyzed Greener Synthesis of Hydrazones in Aqueous Medium Using Microwaves.” American Chemical Society, 48, 32: 5649-5652. (2007). Abstract

EPA Reports

Demonstration of Biodegradation of DNAPL Through Biostimulation and Bioaugmentation at Launch Complex 34 in Cape Canaveral Air Force Station, Florida (PDF) (103 pp, 6.08 MB) (EPA/540/R-07/007) September 2004

Demonstration of In Situ Dehalogenation of DNAPL Through Injection of Emulsified Zero-Valent Iron at Launch Complex 34 in Cape Canaveral Air Force Station, Florida (PDF) (223 pp, 13.2 MB) (EPA/540/R-07/006) September 2007

Grand Plaza Site Investigation Using the Triad Approach and Evaluation of Vapor Intrusion (PDF) (86 pp, 3.2 MB) (EPA/540/R-07/002) September 2006

Measurement of Total Site Mercury Emissions From a Chlor-Alkali Plant Using Open-Path UV-DOAS (PDF) (146 pp, 2.94 MB) (EPA/600/R-07/077) July 2007

Mine Waste Technology Program: A Success Story – CD (EPA/625/C-07/001) 2007 – Abstract

Phase 3 Conference of the U.S.-Germany Bilateral Working Group, Brownfield Revitalization – CD (EPA/625/C-07/002) 2007 – Abstract

Science Brief, Aging Water Infrastructure Research Program, Advanced Concepts (PDF) (2 pp, 352 KB) (EPA/600/F-07/013) September 2007

Science Brief, Aging Water Infrastructure Research Program, Rehabilitation of Wastewater Collection Systems (PDF) (2 pp, 292 KB) (EPA/600/F-07/012) September 2007

Science Brief, Aging Water Infrastructure Research Program, Condition Assessment of Collection Systems (PDF) (2 pp, 328 KB) (EPA/600/F-07/014) September 2007

Xpert Design and Diagnostics’ (XDD) In Situ Chemical Oxidation Process Using Potassium Permanganate (KMNO4) (PDF) (96 pp, 3.75 MB) (EPA/540/R-07/005) May 2007

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