Small-scale and extensive hydrogeomorphic modification and water redistribution in a desert city and implications for regional nitrogen removal

Elisabeth K. Larson, Nancy Grimm

Research output: Contribution to journalArticle

21 Citations (Scopus)

Abstract

There are numerous examples of small-scale hydrogeomorphic manipulations within urban ecosystems. These modifications are motivated both by a need to handle storm drainage and by a human desire for aquatic ecosystems as places for recreation and aesthetics. In the Phoenix Arizona metropolitan area, two examples of these local modifications are artificial lakes and stormwater retention basins. Although lakes are not a natural feature of Sonoran Desert ecosystems, numerous artificial lakes are evident in the region. Retention basins are a common landscaping practice for preventing damage from rare but potentially large storm events. Here we attempt to quantify the heretofore unknown number and extent of these designed aquatic ecosystems and consider their potential impact on hydrologic landscape connectivity and regional nitrogen (N) removal. For lakes, we found that official GIS layers from local and state agencies had significant misclassifications and omissions. We used two published GIS datasets and state impoundment-permit information to determine the number, areal extent, and water source for artificial lakes. We discovered that there are 908-1,390 lakes in the Phoenix area, with the number varying according to level of aggregation. There are no existing GIS data on retention basins, so we employed drywell-permit data to estimate that there may be 10,000 retention basins in the region. Basic data on N stocks in these ecosystems are discussed within the context of the regional N budget. Accurate data on the extent and distribution of these designed ecosystems will be vital for water-resources planning and stormwater management.

Original languageEnglish (US)
Pages (from-to)71-85
Number of pages15
JournalUrban Ecosystems
Volume15
Issue number1
DOIs
StatePublished - Mar 2012

Fingerprint

desert
redistribution
Geographical Information System
water
nitrogen
GIS
stormwater
basin
aquatic ecosystem
ecosystem
lake
natural feature
urban ecosystem
landscape management
impoundment
esthetics
recreation
aggregation
metropolitan area
manipulation

Keywords

  • Artificial lakes
  • Drywells
  • Nitrogen
  • Phoenix, AZ
  • Stormwater retention basins
  • Urban ecology

ASJC Scopus subject areas

  • Urban Studies
  • Ecology

Cite this

Small-scale and extensive hydrogeomorphic modification and water redistribution in a desert city and implications for regional nitrogen removal. / Larson, Elisabeth K.; Grimm, Nancy.

In: Urban Ecosystems, Vol. 15, No. 1, 03.2012, p. 71-85.

Research output: Contribution to journalArticle

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