Vegetation-environment relationships and ecological species groups of an Arizona Pinus ponderosa landscape, USA

Scott R. Abella, Wallace W Covington

Research output: Contribution to journalArticle

24 Citations (Scopus)

Abstract

Pinus ponderosa forests occupy numerous topographic and soil complexes across vast areas of the southwestern United States, yet few data exist on species distributions and vegetation-environment relationships for these environmentally diverse landscapes. We measured topography, soils, and vegetation on 66, 0.05-ha plots within a 110,000-ha P. ponderosa landscape in northern Arizona, USA, to discern vegetation-environment relationships on this landscape. We analyzed associations of environmental variables with plant communities and with single-species distributions, and we classified ecological species groups (co-occurring plant species exhibiting similar environmental affinities). Gradients in community composition paralleled gradients in soil texture, available water, organic C, total N, and geographic precipitation patterns. Soil parent material, affected by the presence or absence of volcanic activity, is a primary factor constraining vegetation patterns on this landscape. Using discriminant analysis, we built a model that correctly classified the most important of four grasses (Bouteloua gracilis, Muhlenbergia montana, Sporobolus interruptus, or Festuca arizonica) on 70-80% of plots based on five environmental variables related to soil moisture and resource levels. We also classified 52 of the 271 detected plant species into 18 ecological species groups. Species groups ranged from Phacelia and Bahia groups occupying xeric, volcanic cinder soils low in organic C and total N, to Festuca and Lathyrus groups characterizing moist, loam and silt loam soils. We applied the species groups by estimating P. ponderosa diameter increment in a regression tree using abundances of species groups. The most rapid P. ponderosa diameter growth of 5 mm/year occurred on plots with high importance of the Festuca and Lathyrus groups. Our results on this semi-arid landscape support several general ecological species group principles chiefly developed in temperate regions, and suggest that vegetation-environment research has great potential for enhancing our understanding of P. ponderosa forests occupying vast areas of the southwestern United States.

Original languageEnglish (US)
Pages (from-to)255-268
Number of pages14
JournalPlant Ecology
Volume185
Issue number2
DOIs
StatePublished - Aug 2006

Fingerprint

Pinus ponderosa
vegetation
Lathyrus
Southwestern United States
Festuca
Muhlenbergia montana
Festuca arizonica
biogeography
Phacelia
Bouteloua gracilis
Sporobolus
soil parent materials
volcanic soils
volcanic activity
loam
environmental factors
soil
silt loam soils
soil resources
soil texture

Keywords

  • Ecosystem classification
  • Forest
  • Ground flora
  • Indicator species
  • Soil
  • Understory

ASJC Scopus subject areas

  • Forestry
  • Plant Science
  • Ecology

Cite this

Vegetation-environment relationships and ecological species groups of an Arizona Pinus ponderosa landscape, USA. / Abella, Scott R.; Covington, Wallace W.

In: Plant Ecology, Vol. 185, No. 2, 08.2006, p. 255-268.

Research output: Contribution to journalArticle

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