Human beings have transformed the Earth into an increasingly urban planet, with nearly half of humanity now living in cities. A city is a unique type of ecosystem where human social, economic, and cultural activities play a prominent role in shaping the landscape, which, in turn, influences the distribution and abundance of other species and consequent patterns of biodiversity. The long-term sustainability of cities is of increasing concern as they continue to grow, straining their infrastructure and pushing against environmental constraints on available natural resources. A key natural resource is water, especially in the more rapidly urbanizing arid regions of the world. Understanding water management and use in cities therefore is critical to developing a deeper theoretical understanding of urban ecosystems as well as effective urban policy. The American West faces a water crisis. Drought, urban growth, climate change, and the continued demands of agriculture have combined to heighten the competition among water users and spurred the search for institutional arrangements to conserve water. Common tools used by governments to regulate and reduce water consumption are the water meter and a use-based pricing structure. In the rapidly urbanizing San Joaquin Valley of California, which is located in an arid region subject to prolonged drought cycles likely to be exacerbated under regional climate change projections, many cities now are installing meters to reduce household water use. Metering is expected to reduce water availability throughout the urban ecosystem, with residential landscaping choices mediating its effects upon the distribution of plants and animals. Urban land-use decisions result from dynamic interactions between institutional and individual-level factors. Landscaping and irrigation at any particular residence, for example, are products of local environmental conditions, the homeowners' cultural preferences, socioeconomic status, neighborhood dynamics, zoning laws, market conditions, city policies, and county/state/federal government regulations. Because land use is a key determinant of habitat for other species, overall urban biodiversity is strongly driven by the outcome of interactions between these variables, but these interactions remain poorly understood. This research project will address the significance of water as a key resource shaping regional patterns of landscape and biodiversity in the Fresno-Clovis metropolitan area of central California. Fresno currently is installing water meters and will start charging for use by 2013, while Clovis has been doing so for almost a century. This contrast in water policies between the two cities provides a unique comparative experimental opportunity to study the impact of metering on human landscaping choices and consequent patterns of urban biodiversity. The objectives of this project are to analyze and contrast current patterns of water use in these cities by focusing on institutional policy and decision making regarding metering; individual homeowner decision making about landscaping; landscape structure at multiple spatial scales; and patterns in the distribution of plant and bird diversity. The investigators will employ a range of methods from multiple disciplines including field observations, institutional and individual homeowner surveys, face-to-face interviews with stakeholders, geographical information systems, remote sensing, global positioning systems, statistical tools, systems modeling, and advanced computer visualization techniques. In addition to addressing many fundamental ecological and socioeconomic questions, the research will be tightly integrated with the education of undergraduate and graduate students and a strong citizen science component built upon the ongoing Fresno Bird Count project.

The project will have significant implications for urban socioecological theory, methodology, and application. In terms of theory, this project will shed light on complex dynamics of interrelated processes among government regulatory policies, human behavior, landscape and habitat structure, and plant and bird distribution at multiple spatial and temporal scales. In terms of methodology, the research will integrate multidisciplinary methods and advanced technologies to investigate the complexity of the study system, leveraging a "natural" experiment occurring due to Fresno's installation of water meters, and involving citizen scientist participation in data gathering. With respect to broader impacts, the project will provide practical information for urban governance by measuring the impact of a common regulatory tool on citizen behavior and its resulting impacts on landscape and biodiversity. Understanding the relationships among institutions, individual citizens, and biodiversity will help guide urban planning towards more sustainable, resilient, and environmentally healthy cities in the region and throughout the world. This award was funded as an Urban Long-Term Research Area Exploratory (ULTRA-Ex) award as the result of a special competition jointly supported by the National Science Foundation and the U.S. Department of Agriculture Forest Service.

Agency
National Science Foundation (NSF)
Institute
Division of Behavioral and Cognitive Sciences (BCS)
Type
Standard Grant (Standard)
Application #
0949036
Program Officer
Thomas J. Baerwald
Project Start
Project End
Budget Start
2010-09-01
Budget End
2014-02-28
Support Year
Fiscal Year
2009
Total Cost
$299,232
Indirect Cost
Name
California State University-Fresno Foundation
Department
Type
DUNS #
City
Fresno
State
CA
Country
United States
Zip Code
93726