Model analysis of integrated surface- and ground-water hydrologic response to climate change

The summary for the Model analysis of integrated surface- and ground-water hydrologic response to climate change grant is detailed below. This summary states who is eligible for the grant, how much grant money will be awarded, current and past deadlines, Catalog of Federal Domestic Assistance (CFDA) numbers, and a sampling of similar government grants. Verify the accuracy of the data FederalGrants.com provides by visiting the webpage noted in the Link to Full Announcement section or by contacting the appropriate person listed as the Grant Announcement Contact. If any section is incomplete, please visit the website for the Bureau of Reclamation Pacific Northwest Region, which is the U.S. government agency offering this grant.
Model analysis of integrated surface- and ground-water hydrologic response to climate change: This Funding Announcement is not a request for applications. This announcement is to provide public notice of the Bureau of Reclamation's intention to fund the following project activities without full and open competition. Concerns for the effects of climate change on water supply and demand have put pressure on to increase reservoir storage. However conservation, regulation, and market-based water trading are also seen as viable strategies for responding to these changes. Increasing reservoir storage is an example of the supply management approach to water management (i.e. water demand is fixed so supply must be increased). Conservation, regulation, and water trading are examples of demand management approaches (i.e. water supply is fixed so demand must be reduced). Coupled hydrologic and economic models are essential tools for addressing questions of where and when supply management and/or demand management approaches are most appropriate for meeting the challenges of global climate change. While surface water and groundwater hydrologic models have long been used as tools for water management decision making, economic modeling is relatively new. Economic models which maximize the utility of a single commodity by maximizing the utility of a social welfare function or net social payoff function are known as partial equilibrium models. Partial equilibrium economic models can be used to maximize the utility of water by determining equilibrium positions between water supply and demand for different water using entities, including agricultural irrigation entities, municipal and industrial (M&I) supply entities, hydropower entities, and environmental and recreational entities. At equilibrium, the quantities of water supplied to and demanded by these entities differ because of differences in (exogenously determined) supply-costs, transportation-costs and demand-prices. As such, partial equilibrium models are a means by which the relative economic valuation of water to different economic sectors can be incorporated into the water management decision making process. In addition, they are a means by which the un-priced economic impacts of large storage projects (referred to by economists as externalities) can also be incorporated into the decision process. Economic externalities are a common result of large storage projects; examples include raised groundwater levels, increased drain returns, new recreational features, and improved wildlife and aquatic habitat. All of which are generally un-priced. Model scenarios were developed to investigate management options associated with new water conservation measures and market-based water trading between these water suppliers and demanders. The development and application of the conjoined Boise Basin spatial water allocation model will take place in three phases.
Federal Grant Title: Model analysis of integrated surface- and ground-water hydrologic response to climate change
Federal Agency Name: Bureau of Reclamation Pacific Northwest Region
Grant Categories: Science and Technology
Type of Opportunity: Discretionary
Funding Opportunity Number: 09SS10WTR003
Type of Funding: Cooperative Agreement
CFDA Numbers: 15.507
CFDA Descriptions: Water 2025
Current Application Deadline: May 04, 2009
Original Application Deadline: May 04, 2009
Posted Date: Apr 17, 2009
Creation Date: Apr 17, 2009
Archive Date: May 05, 2009
Total Program Funding: $203,000
Maximum Federal Grant Award: $203,000
Minimum Federal Grant Award: $0
Expected Number of Awards: 1
Cost Sharing or Matching: No
Applicants Eligible for this Grant
Public and State controlled institutions of higher education
Grant Announcement Contact
Bryant Lyndaker Financial Assistance Officer Phone 208-378-5138

[email protected] [[email protected]]
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