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1 Resilience-based Application of State-and-transition Models D.D. Briske, Texas A&M University B.T. Bestelmeyer, ARS Jornada Tamzen Stringham University of Tamzen Stringham, University of Nevada-Reno Pat Shaver, NRCS Portland Center State-and-transition Model Framework State 2 State 1 Threshold State 3 Community pathway Threshold Community phases within stable states Stringham et al. 2003

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Page 1: Resilience-based Application of State-and-transition Models...1 Resilience-based Application of State-and-transition Models D.D. Briske, Texas A&M University B.T. Bestelmeyer, ARS

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Resilience-based Application of State-and-transition Models

D.D. Briske, Texas A&M University

B.T. Bestelmeyer, ARS Jornada

Tamzen Stringham University ofTamzen Stringham, University of Nevada-RenoPat Shaver, NRCS Portland Center

State-and-transition Model Framework

State 2State 1

Threshold

State 3

Community pathway

Threshold

Community phases within stable states

Stringham et al. 2003

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Woody State

Multiple Stable State Concept

Grass StateTallgrass Grass State

Eroded State

G ass S a eShortgrass

Briske et al. 2005

Professional Reinvention

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Ecological Site Descriptions: Ecosystem Management Framework

ESD ConceptS&T ModelsThresholds

Range Health

Other AgenciesTo Adopt

Presentation ObjectivesPropose several recommendations to make ecological resilience more explicit in STMsIllustrate application to STM frameworkEmphasize the potential value of resilience-based STM’s

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Thresholds vs Resilience

Thresholds ResilienceThresholds Resilience

Resilience – extent of modification required to transform an ecosystem to an alternative state. Threshold – defines the limits of resilience for an ecosystem.

Resilience-based Management

State I State II

Feedback switch

ThresholdTrigger

Ecological Resilience Ecological Resilience

State I State II

Community Phase

Community Phase

At-risk Community Restoration

pathway

Positive Feedbacks Positive Feedbacks

Negative Feedbacks Negative Feedbacks

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Resilience-based Concepts

At-risk community phase - plant community phase that is most vulnerable to exceeding state resilience.

Feedback mechanisms - ecological processes that enhance (negative) or decrease (positive) ecosystem resilience.

Feedback switch – point at which feedbacks shift from negative to positive and exceed resilience limits.

Restoration pathways – re-establishment of pre-threshold states following active restoration of autogenic repair mechanisms.

Triggers - variables or events that initiate thresholds by contributing to the immediate loss of ecosystem resilience.

Ecological ResilienceEcological Resilience

Resilience-based STMs

Feedback switch

Threshold

Restoration pathway

Negative Feedbacks

Ecological Resilience

State 2

Negative Feedbacks

Ecological Resilience

State 1

Positive Feedbacks

Negative Feedbacks

Positive Feedbacks

Negative Feedbacks

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Grassland State

Woodland State

Threshold

Progression

Positive and Negative Feedbacks

Positive Feedbacks• woody plant cover• coarse fuel loads• propagule limitations

ck S

witch

Progression

Negative Feedbacks• grassland productivity• fine, continuous fuel loads• propogule limitations

Feed

bac

cks

Nega

T i

Feedback Switch - Thresholds

Posi

tive

Feed

bac ative Feedbacks

Trigger

NFB’s > PFB’s

NFB’s = PFB’sFeedback switch

NFB’s > PFB’s

Time

P NFB s > PFB sPost-threshold state

NFB s > PFB sPre-threshold state

Briske et al. 2006

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cks

Nega

T i

Feedback Switch – Restoration Pathways

Posi

tive

Feed

bac ative Feedbacks

Trigger

NFB’s > PFB’s

NFB’s = PFB’sFeedback switch

NFB’s > PFB’s

Time

P NFB s > PFB sPost-threshold state

NFB s > PFB sPre-threshold state

Briske et al. 2006

Restoration Pathways

The re-establishment of former states following active restoration of autogenicfollowing active restoration of autogenic repair mechanisms and feedbacks.Minimizes the inconsistency of suggesting that thresholds are reversible, which they are not without management intervention. Provide information concerning the probability and type or restoration required.

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Benefits of Resilience-based STMs

Explicitly connect the STM framework to ecological resilience e g relevance to broaderecological resilience e.g., relevance to broader ecological community Refocus management attention toward attributes and management actions that affect resilience in addition to thresholds e.g., threshold are undefined endpointsundefined endpointsCapture a broader set of variables necessary to anticipate and identify resilience e.g. excessive emphasis on management variables

Benefits Justification

Resilience-based management emphasizes h di i d d i h i flthe conditions and dynamics that influence state proximity and vulnerability to thresholds. This distinction increases the ability to manage ecosystem change rather than merely react to it. Adaptive management can maintaining state resilience without necessarily affecting the conditions that precipitate thresholds.

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Bridging Theory and Application

Non-Equilibrium Ecological SiteqParadigm

gDescriptions

Multiple Stable States

State & TransitionModels

Multiple Pathways

Ecological Thresholds

Thresholds

RangelandHealth

Indicators and Assessment

State Vulnerability to ThresholdsTriggersTriggersFeedbacks

Potential Restoration PathwaysResilience of Alternative StateResidual Properties of Former State

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Indicators and Assessment Triggers

Indicators AssessmentIndicators AssessmentDrought Weather record, mortalityFire regimes History, spp compositionGrazing History, spp. compositionInvasive spp Spread dominanceInvasive spp. Spread, dominanceEpisodic events Climate records, soil loss

Indicators and Assessment Feedbacks

SoilsBare soil/patch sizeSoil/nutrient redistribution

VegetationFunctional group lossIncrease invasive speciesp

FunctionProductivityRunoff rate and pattern

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Indicators and AssessmentPotential Restoration Pathways

Resilience of Alternative StateResilience of Alternative StateFunctional group compositionSoil modification

Residual properties of Former StateReproductive plants/seedS il/ t i t il bilitSoil/nutrient availability

Reference StateIndicators: High perennial grass cover, minimal soil movement, bare patches small and unconnected.

Draw Ecological Site, New Mexico

Restoration Pathway: Gully plugs

At-risk Community Phase: Perennial grass cover low,patchy, with large interconnected areas of bare ground in response to intensive grazing and drought.

Trigger: Intensive grazing/drought that predisposes site to gully formation following intense rainfall event.

Threshold: Gully development channels water, soil and nutrients away from grasses, initiates greater soil erosion,

, pFeedbacks: Perennial grasses minimize soil, nutrient and water movement from high-intensity storms.

TobosaAlkali sacaton

Patchy tobosa(Mesquite)

Tobosa(low diversity

Alternative State Indicators: Major soil and water movement, gullies continue to deepen, and shortgrass dominance.Feedbacks: Few perennial grasses and continued water, soil and nutrient losses with subsequent rain storms that lead to additional grass loss.

Restoration Pathway: Gully plugsand water spreaders to slow andredistribute water movement tofacilitate grass recolonization.May require decades with periodic maintenance and light grazing.

Burrograss/tobosa, Patchy mesquite

y g , g ,and leads to additional grass loss.

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Reference StateIndicators: High perennial grass cover, dispersed sagebrush cover, minimal juniper and bare soil. Feedbacks: Herbaceous cover retains water on site and provides fuel to support a fire return i t l f l th 50

Mountain Clay Ecological Site, OregonIdaho FescueBluebunchwheatgrass Idaho Fescue

BluebunchwheatgrassMountain big

b hIdaho Fescue

At-risk Community Phase: Herbaceous cover reduced, sagebrush decadence, juniper visible and bare soil patches increasing, potential fire frequency reduced.

Trigger: Drought and intensive grazing promote juniper establishment through reduced fire frequency.

interval of less than 50 years.

Threshold: Juniper attains a height and density that reduces fine fuel load and fire-induced tree mortality. Large, inter-connected bare soil patches occur with

di ib i f i / il b h j i iRestoration Pathway: Bunchgrass

gsagebrushJuniper

Idaho FescueBluebunchwheatgrassMountain big sagebrush

JuniperSagebrushIdaho FescueBluebunchwheatgrass

redistribution of nutrients/soil beneath juniper canopies.Restoration Pathway: Bunchgrass (BG) density > 1 m2 requires mechanical juniper removal only;BG density < 1 m2 requires juniper removaland grass reseeding, if soil is intact.

Alternative State Indicators: Mature juniper dominant, Idaho fescue only beneath juniper canopies, large interconnected bare soil patches, sagebrush decadence.. Feedbacks: Juniper dominates resource use, water and wind redistribute soil and nutrients beneath juniper, minimal grass and sagebrush establishment .

JuniperIdaho FescueSandberg bluegrass

Potential Value AddedResilience-based STMs will promote adaptive management by emphasizing assessment of state resilience in addition to threshold identification. Identify additional resilience indicators to better inform ecosystem managers of risk and restoration options. Promote greater international dialogue between ecologists and ecosystem managers on the general

t f t d inature of ecosystem dynamics.