Shifts in community-level traits and functional diversity in a mixed conifer forest: a legacy of land-use change

1. Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creat...

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Veröffentlicht in:The Journal of applied ecology Jg. 53; H. 6; S. 1755 - 1765
Hauptverfasser: Strahan, Robert T., Meador, Andrew J. Sánchez, Huffman, David W., Laughlin, Daniel C.
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Oxford John Wiley & Sons Ltd 01.12.2016
Blackwell Publishing Ltd
Schlagworte:
Abies concolor
Arizona
Bark
bark thickness
Biodiversity
Climate change
community structure
Coniferous forests
Coniferous trees
Dendrochronology
drought
Drought resistance
drought tolerance
Ecosystem degradation
Ecosystem resilience
Ecosystem restoration
Ecosystem structure
Ecosystems
Environmental stress
fire regime
fire resistance
Forest management
Forests
frequent fires
functional diversity
functional traits
Land use
land use change
leaf area
leaf economics
leaf nitrogen
Leaves
mixed conifer forest
Mixed forests
nitrogen content
Pinus strobiformis
Plants
Precipitation
Species composition
species diversity
specific leaf area
Wood
wood density
Arizona
ISSN:0021-8901, 1365-2664
Online-Zugang:Volltext
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Abstract 1. Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental Stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long-term changes in stand-level functional traits are not well understood. 2. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre-settlement and contemporary forest composition, structure and community-weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. 3. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. 4. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
AbstractList 1. Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long-term changes in stand-level functional traits are not well understood. 2. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre-settlement and contemporary forest composition, structure and community-weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. 3. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. 4. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
Summary Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long‐term changes in stand‐level functional traits are not well understood. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre‐settlement and contemporary forest composition, structure and community‐weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land‐use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand‐level bark thickness to promote fire tolerance and increasing stand‐level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land‐use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand‐level bark thickness to promote fire tolerance and increasing stand‐level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
1. Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental Stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long-term changes in stand-level functional traits are not well understood. 2. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre-settlement and contemporary forest composition, structure and community-weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. 3. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. 4. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long‐term changes in stand‐level functional traits are not well understood. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA . We analysed the differences in pre‐settlement and contemporary forest composition, structure and community‐weighted mean ( CWM ) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area ( SLA ), wood density and bark thickness. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis . Compositional changes were associated with declines in CWM leaf N, SLA , wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. Synthesis and applications . Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land‐use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand‐level bark thickness to promote fire tolerance and increasing stand‐level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land‐use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand‐level bark thickness to promote fire tolerance and increasing stand‐level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
Summary Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long-term changes in stand-level functional traits are not well understood. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre-settlement and contemporary forest composition, structure and community-weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land-use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand-level bark thickness to promote fire tolerance and increasing stand-level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered disturbance regimes are calling into question the usefulness of this approach. As a consequence, restoration goals are increasingly focused on creating communities that are resilient to novel environmental stressors and emphasis is being placed on defining functional targets through the use of plant traits. While changes in forest structure and composition have received much attention, long‐term changes in stand‐level functional traits are not well understood. We used dendrochronology to reconstruct historical forest structure and composition in 1880, the year immediately following the disruption of the natural fire regime in a mixed conifer forest in Arizona, USA. We analysed the differences in pre‐settlement and contemporary forest composition, structure and community‐weighted mean (CWM) traits, and functional diversity metrics (Rao's Q and functional richness) for four plant functional traits: leaf nitrogen content (leaf N), specific leaf area (SLA), wood density and bark thickness. We observed significant shifts in forest composition, structure, CWM traits and functional diversity from 1880 to 2011. These changes reflect a reduction in fire and drought tolerance, driven largely by increases in the relative importance of Abies concolor and Pinus strobiformis. Compositional changes were associated with declines in CWM leaf N, SLA, wood density and bark thickness. We found lower multitrait functional diversity (Rao's Q) in contemporary forests driven primarily by leaf N; however, bark thickness variation was greater in contemporary forests than in 1880. Synthesis and applications. Compositional shifts towards reduced average bark thickness and wood density in contemporary forests driven by land‐use change have likely reduced forest resilience to both fire and drought. Managers can manipulate forest structure and species composition to achieve functional objectives by increasing stand‐level bark thickness to promote fire tolerance and increasing stand‐level wood density to promote drought tolerance. Forecasts for extended fire seasons along with declining precipitation are projected for many ecosystems around the planet. A focus on restoring optimal functional trait combinations may be as important as managing ecosystem structure for restoring resilient ecosystems.
Author Huffman, David W.
Strahan, Robert T.
Laughlin, Daniel C.
Meador, Andrew J. Sánchez
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Snippet 1. Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered...
Summary Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered...
Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered...
Summary Historical reference conditions have long been used to guide the restoration of degraded ecosystems. However, a rapidly changing climate and altered...
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StartPage 1755
SubjectTerms Abies concolor
Arizona
Bark
bark thickness
Biodiversity
Climate change
community structure
Coniferous forests
Coniferous trees
Dendrochronology
drought
Drought resistance
drought tolerance
Ecosystem degradation
Ecosystem resilience
Ecosystem restoration
Ecosystem structure
Ecosystems
Environmental stress
fire regime
fire resistance
Forest management
Forests
frequent fires
functional diversity
functional traits
Land use
land use change
leaf area
leaf economics
leaf nitrogen
Leaves
mixed conifer forest
Mixed forests
nitrogen content
Pinus strobiformis
Plants
Precipitation
Species composition
species diversity
specific leaf area
Wood
wood density
Title Shifts in community-level traits and functional diversity in a mixed conifer forest: a legacy of land-use change
URI https://www.jstor.org/stable/44133931
https://onlinelibrary.wiley.com/doi/abs/10.1111%2F1365-2664.12737
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https://www.proquest.com/docview/1850780877
https://www.proquest.com/docview/2000335257
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