Restoring forest resilience: From reference spatial patterns to silvicultural prescriptions and monitoring

► We quantified stand-level pattern in terms of individual trees, clumps, and openings. ► We used AET and Deficit to develop climate analog reference conditions. ► We developed a method to translate reference patterns into prescription guidelines. ► Our ICO method created patterns in agreement with...

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Bibliographic Details
Published in:Forest ecology and management Vol. 291; pp. 442 - 457
Main Authors: Churchill, Derek J., Larson, Andrew J., Dahlgreen, Matthew C., Franklin, Jerry F., Hessburg, Paul F., Lutz, James A.
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01.03.2013
Elsevier
Subjects:
adaptation
Animal and plant ecology
Animal, plant and microbial ecology
basal area
Biological and medical sciences
case studies
Climate
Climate analogs
climate change
Clumps
coniferous forests
ecosystems
fire regime
forest fires
Forest management. Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Forest restoration
Forestry
Forests
Fuels treatments
Fundamental and applied biological sciences. Psychology
habitats
historic sites
monitoring
mortality
Mosaics
Reference conditions
Regeneration
Resilience
Restoration
snow
Spatial pattern
stand basal area
stand structure
Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Synecology
Terrestrial ecosystems
Trees
water balance
Spatial pattern
Fuels treatments
Forest restoration
Climate analogs
Resilience
Reference conditions
Prescription
Climate
Forests
Silviculture
Forest ecology
Physical environment
Spatial distribution
Surveillance
Fuel
Forestry
Ecological recovery
ISSN:0378-1127, 1872-7042
Online Access:Get full text
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Summary:► We quantified stand-level pattern in terms of individual trees, clumps, and openings. ► We used AET and Deficit to develop climate analog reference conditions. ► We developed a method to translate reference patterns into prescription guidelines. ► Our ICO method created patterns in agreement with reference conditions. ► Reference spatial patterns offer a proven resilience strategy. Stand-level spatial pattern influences key aspects of resilience and ecosystem function such as disturbance behavior, regeneration, snow retention, and habitat quality in frequent-fire pine and mixed-conifer forests. Reference sites, from both pre-settlement era reconstructions and contemporary forests with active fire regimes, indicate that frequent-fire forests are complex mosaics of individual trees, tree clumps, and openings. There is a broad scientific consensus that restoration treatments should seek to restore this mosaic pattern in order to restore resilience and maintain ecosystem function. Yet, methods to explicitly incorporate spatial reference information into restoration treatments are not widely used. In addition, targets from reference conditions must be critically evaluated in light of climate change. We used a spatial clump identification algorithm to quantify reference patterns based on a specified inter-tree distance that defines when trees form clumps. We used climatic water balance parameters, downscaled climate projections, and plant associations to assess our historical reference sites in the context of projected future climate and identify climate analog reference conditions. Spatial reference information was incorporated into a novel approach to prescription development, tree marking, and monitoring based on viewing stand structure and pattern in terms of individuals, clumps, and openings (ICO) in a mixed-conifer forest restoration case study. We compared the results from the ICO approach with simulations of traditional basal area and spacing-based thinning prescriptions in terms of agreement with reference conditions and functional aspects of resilience. The ICO method resulted in a distribution of tree clumps and openings within the range of reference patterns, while the basal area and spacing approaches resulted in uniform patterns inconsistent with known reference conditions. Susceptibility to insect mortality was lower in basal area and spacing prescriptions, but openings and corresponding opportunities for regeneration and in situ climate adaptation were fewer. Operationally, the method struck a balance between providing clear targets for spatial pattern directly linked to reference conditions, sufficient flexibility to achieve other restoration objectives, and implementation efficiency. The need to track pattern targets during implementation and provide immediate feedback to marking crews was a key lesson. The ICO method, especially when used in combination with climate analog reference targets, offers a practical approach to restoring spatial patterns that are likely to enhance resilience and climate adaptation.
Bibliography:http://dx.doi.org/10.1016/j.foreco.2012.11.007
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ISSN:0378-1127
1872-7042
DOI:10.1016/j.foreco.2012.11.007