Forest ecosystems of an Arizona Pinus ponderosa landscape

Multifactor classification and implications for ecological restoration

Scott R. Abella, Wallace W Covington

Research output: Contribution to journalArticle

23 Citations (Scopus)

Abstract

Aim: We developed an ecosystem classification within a 110,000-ha Arizona Pinus ponderosa P. & C. Lawson (ponderosa pine) landscape to support ecological restoration of these forests. Specific objectives included identifying key environmental variables constraining ecosystem distribution and comparing plant species composition, richness and tree growth among ecosystems. Location: The Coconino National Forest and the Northern Arizona University Centennial Forest, in northern Arizona, USA. Methods: We sampled geomorphology, soils and vegetation on 66 0.05-ha plots in open stands containing trees of pre-settlement (c. 1875) origin, and on 26 plots in dense post-settlement stands. Using cluster analysis and ordination of vegetation and environment matrices, we classified plots into ecosystem types internally similar in environmental and vegetational characteristics. Results: We identified 10 ecosystem types, ranging from dry, black cinders/ Phacelia ecosystems to moist aspen/Lathyrus ecosystems. Texture, organic carbon and other soil properties reflecting the effects of parent materials structured ecosystem distribution across the landscape, and geomorphology was locally important. Plant species composition was ecosystem-specific, with C3 Festuca arizonica Vasey (Arizona fescue), for instance, abundant in mesic basalt/Festuca ecosystems. Mean P. ponderosa diameter increments ranged from 2.3-4.3 mm year-1 across ecosystems in stands of pre-settlement origin, and the ecosystem classification was robust in dense post-settlement stands. Main conclusions: Several lines of evidence suggest that although species composition may have been altered since settlement, the same basic ecosystems occurred on this landscape in pre-settlement forests, providing reference information for ecological restoration. Red cinders/Bahia ecosystems were rare historically and > 30% of their area has been burned by crown fires since 1950, indicating that priority could be given to restoring this ecosystem's remaining mapping units. Ecosystem classifications may be useful as data layers in gap analyses to identify restoration and conservation priorities. Ecosystem turnover occurs at broad extents on this landscape, and restoration must accordingly operate across large areas to encompass ecosystem diversity. By incorporating factors driving ecosystem composition, this ecosystem classification represents a framework for estimating spatial variation in ecological properties, such as species diversity, relevant to ecological restoration.

Original languageEnglish (US)
Pages (from-to)1368-1383
Number of pages16
JournalJournal of Biogeography
Volume33
Issue number8
DOIs
StatePublished - Aug 2006

Fingerprint

ecological restoration
Pinus ponderosa
forest ecosystems
restoration
forest ecosystem
taxonomy
ecosystems
ecosystem
Festuca arizonica
cluster analysis
turnover
parents
species diversity
conservation
geomorphology
Coconino National Forest
evidence
Phacelia
Lathyrus
vegetation

Keywords

  • Arizona
  • Conservation biogeography
  • Ecosystem classification
  • Geomorphology
  • Pinus ponderosa
  • Reference conditions
  • Soil
  • Species richness
  • Terrestrial ecosystem survey
  • Vegetation-environment relationships

ASJC Scopus subject areas

  • Ecology
  • Geography, Planning and Development

Cite this

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title = "Forest ecosystems of an Arizona Pinus ponderosa landscape: Multifactor classification and implications for ecological restoration",
abstract = "Aim: We developed an ecosystem classification within a 110,000-ha Arizona Pinus ponderosa P. & C. Lawson (ponderosa pine) landscape to support ecological restoration of these forests. Specific objectives included identifying key environmental variables constraining ecosystem distribution and comparing plant species composition, richness and tree growth among ecosystems. Location: The Coconino National Forest and the Northern Arizona University Centennial Forest, in northern Arizona, USA. Methods: We sampled geomorphology, soils and vegetation on 66 0.05-ha plots in open stands containing trees of pre-settlement (c. 1875) origin, and on 26 plots in dense post-settlement stands. Using cluster analysis and ordination of vegetation and environment matrices, we classified plots into ecosystem types internally similar in environmental and vegetational characteristics. Results: We identified 10 ecosystem types, ranging from dry, black cinders/ Phacelia ecosystems to moist aspen/Lathyrus ecosystems. Texture, organic carbon and other soil properties reflecting the effects of parent materials structured ecosystem distribution across the landscape, and geomorphology was locally important. Plant species composition was ecosystem-specific, with C3 Festuca arizonica Vasey (Arizona fescue), for instance, abundant in mesic basalt/Festuca ecosystems. Mean P. ponderosa diameter increments ranged from 2.3-4.3 mm year-1 across ecosystems in stands of pre-settlement origin, and the ecosystem classification was robust in dense post-settlement stands. Main conclusions: Several lines of evidence suggest that although species composition may have been altered since settlement, the same basic ecosystems occurred on this landscape in pre-settlement forests, providing reference information for ecological restoration. Red cinders/Bahia ecosystems were rare historically and > 30{\%} of their area has been burned by crown fires since 1950, indicating that priority could be given to restoring this ecosystem's remaining mapping units. Ecosystem classifications may be useful as data layers in gap analyses to identify restoration and conservation priorities. Ecosystem turnover occurs at broad extents on this landscape, and restoration must accordingly operate across large areas to encompass ecosystem diversity. By incorporating factors driving ecosystem composition, this ecosystem classification represents a framework for estimating spatial variation in ecological properties, such as species diversity, relevant to ecological restoration.",
keywords = "Arizona, Conservation biogeography, Ecosystem classification, Geomorphology, Pinus ponderosa, Reference conditions, Soil, Species richness, Terrestrial ecosystem survey, Vegetation-environment relationships",
author = "Abella, {Scott R.} and Covington, {Wallace W}",
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TY - JOUR

T1 - Forest ecosystems of an Arizona Pinus ponderosa landscape

T2 - Multifactor classification and implications for ecological restoration

AU - Abella, Scott R.

AU - Covington, Wallace W

PY - 2006/8

Y1 - 2006/8

N2 - Aim: We developed an ecosystem classification within a 110,000-ha Arizona Pinus ponderosa P. & C. Lawson (ponderosa pine) landscape to support ecological restoration of these forests. Specific objectives included identifying key environmental variables constraining ecosystem distribution and comparing plant species composition, richness and tree growth among ecosystems. Location: The Coconino National Forest and the Northern Arizona University Centennial Forest, in northern Arizona, USA. Methods: We sampled geomorphology, soils and vegetation on 66 0.05-ha plots in open stands containing trees of pre-settlement (c. 1875) origin, and on 26 plots in dense post-settlement stands. Using cluster analysis and ordination of vegetation and environment matrices, we classified plots into ecosystem types internally similar in environmental and vegetational characteristics. Results: We identified 10 ecosystem types, ranging from dry, black cinders/ Phacelia ecosystems to moist aspen/Lathyrus ecosystems. Texture, organic carbon and other soil properties reflecting the effects of parent materials structured ecosystem distribution across the landscape, and geomorphology was locally important. Plant species composition was ecosystem-specific, with C3 Festuca arizonica Vasey (Arizona fescue), for instance, abundant in mesic basalt/Festuca ecosystems. Mean P. ponderosa diameter increments ranged from 2.3-4.3 mm year-1 across ecosystems in stands of pre-settlement origin, and the ecosystem classification was robust in dense post-settlement stands. Main conclusions: Several lines of evidence suggest that although species composition may have been altered since settlement, the same basic ecosystems occurred on this landscape in pre-settlement forests, providing reference information for ecological restoration. Red cinders/Bahia ecosystems were rare historically and > 30% of their area has been burned by crown fires since 1950, indicating that priority could be given to restoring this ecosystem's remaining mapping units. Ecosystem classifications may be useful as data layers in gap analyses to identify restoration and conservation priorities. Ecosystem turnover occurs at broad extents on this landscape, and restoration must accordingly operate across large areas to encompass ecosystem diversity. By incorporating factors driving ecosystem composition, this ecosystem classification represents a framework for estimating spatial variation in ecological properties, such as species diversity, relevant to ecological restoration.

AB - Aim: We developed an ecosystem classification within a 110,000-ha Arizona Pinus ponderosa P. & C. Lawson (ponderosa pine) landscape to support ecological restoration of these forests. Specific objectives included identifying key environmental variables constraining ecosystem distribution and comparing plant species composition, richness and tree growth among ecosystems. Location: The Coconino National Forest and the Northern Arizona University Centennial Forest, in northern Arizona, USA. Methods: We sampled geomorphology, soils and vegetation on 66 0.05-ha plots in open stands containing trees of pre-settlement (c. 1875) origin, and on 26 plots in dense post-settlement stands. Using cluster analysis and ordination of vegetation and environment matrices, we classified plots into ecosystem types internally similar in environmental and vegetational characteristics. Results: We identified 10 ecosystem types, ranging from dry, black cinders/ Phacelia ecosystems to moist aspen/Lathyrus ecosystems. Texture, organic carbon and other soil properties reflecting the effects of parent materials structured ecosystem distribution across the landscape, and geomorphology was locally important. Plant species composition was ecosystem-specific, with C3 Festuca arizonica Vasey (Arizona fescue), for instance, abundant in mesic basalt/Festuca ecosystems. Mean P. ponderosa diameter increments ranged from 2.3-4.3 mm year-1 across ecosystems in stands of pre-settlement origin, and the ecosystem classification was robust in dense post-settlement stands. Main conclusions: Several lines of evidence suggest that although species composition may have been altered since settlement, the same basic ecosystems occurred on this landscape in pre-settlement forests, providing reference information for ecological restoration. Red cinders/Bahia ecosystems were rare historically and > 30% of their area has been burned by crown fires since 1950, indicating that priority could be given to restoring this ecosystem's remaining mapping units. Ecosystem classifications may be useful as data layers in gap analyses to identify restoration and conservation priorities. Ecosystem turnover occurs at broad extents on this landscape, and restoration must accordingly operate across large areas to encompass ecosystem diversity. By incorporating factors driving ecosystem composition, this ecosystem classification represents a framework for estimating spatial variation in ecological properties, such as species diversity, relevant to ecological restoration.

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KW - Conservation biogeography

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KW - Geomorphology

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KW - Reference conditions

KW - Soil

KW - Species richness

KW - Terrestrial ecosystem survey

KW - Vegetation-environment relationships

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