Abstract
Problem, research strategy, and findings
Patterns of change in urban surfaces have implications for equity, health, and environmental quality in future cities and for their adaptability to climate change. Relatively little detailed research has been done on the role of land use policies—particularly the recent generation of infill and climate adaptation policies—in shaping urban surfaces and related environmental systems. I used a novel approach integrating three methods—land use change models, urban form assessments, and policy-based scenarios—to evaluate patterns of change. I applied these methods to a case study simulation of future development in Denver (CO) and used a stormwater management example to evaluate the capacity of the local management system to treat expansion of the city’s hardscape. I found that the proportion of impervious cover in the city is projected to increase substantially, possibly to levels discussed in the literature as severely affected. A major social commitment to adaptation policies such as green infrastructure would be necessary to mitigate projected hardscape increases. Dispersed development strategies generate substantially more hardscape than geographically targeted development, which suggests that there is also untapped potential for climate adaptation in general land use policy. I share common limitations of scenario-based methods.
Takeaway for practice
Changes in the composition of urban surfaces in the next 2 decades could have significant environmental effects. In this research, I developed and tested methods that bridge infrastructure and land use planning practices—the public works and community planning silos in local governments—to evaluate these processes and effects. These methods should be useful in many cities.
Acknowledgments
We acknowledge the city of Denver, University of Colorado, and Trust for Public Lands for their support of green infrastructure research at the University of Colorado, and the contributions of research assistants including Mehdi Heris.
Supplemental Material
Supplemental data for this article can be accessed online at https://doi.org/10.1080/01944363.2023.2214121.
Data Availability Statement
Most of this research relied on already published data sets. Sharing of other data is limited by confidentiality restrictions.
Additional information
Notes on contributors
Brian Muller
BRIAN MULLER ([email protected]) is associate professor emeritus at the University of Colorado Boulder.
Stefania Mitova
STEFANIA MITOVA ([email protected]) collaborated in this research as a PhD student in environmental studies at the University of Colorado Boulder, CO.