Urban park systems to support sustainability

The role of urban park systems in hot arid urban climates

Gunwoo Kim, Paul Coseo

Research output: Contribution to journalArticleResearchpeer-review

4 Citations (Scopus)

Abstract

Quantifying ecosystem services in urban areas is complex. However, existing ecosystem service typologies and ecosystem modeling can provide a means towards understanding some key biophysical links between urban forests and ecosystem services. This project addresses broader concepts of sustainability by assessing the urban park system in Phoenix, Arizona's hot urban climate. This project aims to quantify and demonstrate the multiple ecosystem services provided by Phoenix's green infrastructure (i.e., urban park system), including its air pollution removal values, carbon sequestration and storage, avoided runoff, structural value, and the energy savings it provides for city residents. Modeling of ecosystem services of the urban park system revealed around 517,000 trees within the system, representing a 7.20% tree cover. These trees remove about 3630 tons (t) of carbon (at an associated value of $285,000) and about 272 t of air pollutants (at an associated value of $1.16 million) every year. Trees within Phoenix's urban park system are estimated to reduce annual residential energy costs by $106,000 and their structural value is estimated at $692 million. The findings of this research will increase our knowledge of the value of green infrastructure services provided by different types of urban vegetation and assist in the future design, planning and management of green infrastructure in cities. Thus, this study has implications for both policy and practice, contributing to a better understanding of the multiple benefits of green infrastructure and improving the design of green spaces in hot arid urban climates around the globe.

Original languageEnglish
Article number439
JournalForests
Volume9
Issue number7
DOIs
StatePublished - 2018 Jul 22

Fingerprint

urban climate
green infrastructure
ecosystem service
ecosystem services
sustainability
climate
infrastructure
carbon sequestration
residential energy
design for environment
ecosystem modeling
air pollution
energy costs
typology
urban areas
runoff
atmospheric pollution
planning
urban area
pollutants

Keywords

  • Ecosystem modeling
  • Ecosystem services
  • Environmental quality
  • Hot arid urban climate
  • Human health
  • Sustainability

Cite this

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abstract = "Quantifying ecosystem services in urban areas is complex. However, existing ecosystem service typologies and ecosystem modeling can provide a means towards understanding some key biophysical links between urban forests and ecosystem services. This project addresses broader concepts of sustainability by assessing the urban park system in Phoenix, Arizona's hot urban climate. This project aims to quantify and demonstrate the multiple ecosystem services provided by Phoenix's green infrastructure (i.e., urban park system), including its air pollution removal values, carbon sequestration and storage, avoided runoff, structural value, and the energy savings it provides for city residents. Modeling of ecosystem services of the urban park system revealed around 517,000 trees within the system, representing a 7.20{\%} tree cover. These trees remove about 3630 tons (t) of carbon (at an associated value of $285,000) and about 272 t of air pollutants (at an associated value of $1.16 million) every year. Trees within Phoenix's urban park system are estimated to reduce annual residential energy costs by $106,000 and their structural value is estimated at $692 million. The findings of this research will increase our knowledge of the value of green infrastructure services provided by different types of urban vegetation and assist in the future design, planning and management of green infrastructure in cities. Thus, this study has implications for both policy and practice, contributing to a better understanding of the multiple benefits of green infrastructure and improving the design of green spaces in hot arid urban climates around the globe.",
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Urban park systems to support sustainability : The role of urban park systems in hot arid urban climates. / Kim, Gunwoo; Coseo, Paul.

In: Forests, Vol. 9, No. 7, 439, 22.07.2018.

Research output: Contribution to journalArticleResearchpeer-review

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