The document discusses assessing climate change vulnerability for ecosystems in the Southeast and Caribbean. It describes a two-phase approach: Phase 1 qualitatively assesses sensitivity, exposure, and adaptive capacity based on literature and GIS data for 12 ecosystems. Phase 2 quantitatively assesses vulnerability for two ecosystems using the Habitat Climate Change Vulnerability Index, which calculates climate stress, envelope shift, and overall vulnerability scores. The assessment finds moderate to high vulnerability for the ecosystems studied. It identifies uncertainties and needs for incorporating additional factors and assessing more ecosystems.
1. Assessing climate change vulnerability of
ecosystems in the Southeast (and Caribbean)
Jennifer Costanza
April 9, 2015
2. Vulnerability assessments: a key step in adaptation planning
USFWS 2010 Climate Change Strategy
Objective:
Develop Expertise In and Conduct Adaptation
Planning for Key Species and Habitats
National Fish, Wildlife, and Plants Climate
Adaptation Strategy 2012:
Vulnerability assessments are important for
management planning and decision-making
under uncertainty.
Glick et al. 2011 Scanning the Conservation
Horizon:
Vulnerability assessments are the first steps
to facilitating ecosystem resistance and
resilience to climate change.
5. Objective
Assess climate change vulnerability for a set of
ecosystems in the Southeast and Caribbean.
• Phase 1: Synthesize literature and GIS data on
sensitivity, exposure, and adaptive capacity for 12
ecosystems
• Phase 2: Use NatureServe’s Habitat Climate Change
Vulnerability Index (HCCVI) for 2 of these ecosystems
7. Approach: Ecosystem selection
Initial criteria: likely to be sensitive to climate change
• Coastal or coastal plain regions
• Wetlands
• High elevation systems
• Endemic to geographically discrete conditions, special soils
or other unique environments
• IUCN Threatened
• Suggestions from LCCs
Resulted in a list of 55 potential ecosystems in the Southeast
and Caribbean.
8. Approach: Ecosystem selection
Ecosystem (NatureServe Ecological System)
Caribbean Coastal Mangrove
Caribbean Montane Wet Elfin Forest
Central Atlantic Coastal Plain Wet Longleaf Pine Savanna and Flatwoods
Central Florida Wet Prairie and Herbaceous Seep
East Gulf Coastal Plain Near-coast Pine Flatwoods
East Gulf Coastal Plain Southern Loess Bluff Forest
Edwards Plateau Limestone Shrubland
Edwards Plateau Mesic Canyon
Nashville Basin Limestone Glade and Woodland
South-Central Interior Mesophytic Forest
Southern Coastal Plain Nonriverine Cypress Dome
Southern Coastal Plain Seepage Swamp and Baygall
10. Vulnerability assessments for ecosystems or habitats are
more challenging.
St. Mark’s National Wildlife Refuge. Credit: Alan Cressler
11. Cedar glade, Rutherford Co., TN, Credit: Alan Cressler
Vulnerability assessments for ecosystems or habitats are
more challenging.
12. Phase 1 assessment approach
Climate factors that affect:
• Distribution of the ecosystem
• Important ecological processes
• Dominant plant species
• Plant and animal species of conservation importance
Focus on:
• Non-climate stressors
• Ecosystem function
• Total area
• Connectivity
• Environmental/topographic complexity
• Area protected and managed
Qualitative, relative vulnerability rating
13. Phase 1 major GIS data
Sensitivity
• WorldClim 1950-1999 data: seasonal max and min temperature, total precipitation
Exposure
• Downscaled climate projections (K. Hayhoe et al.), averaged across GCMs for
A1FI and B1 scenarios, 2040-2060, 2080-2100
• NOAA sea level rise: recent data and projections for 1 ft and 6 ft rise
• Sea level rise vegetation impacts from SLAMM modeling
Adaptive Capacity
• Current ecosystem total area (GAP land cover)
• Mean patch size (GAP land cover)
• Proportion under conservation protection (US Protected Areas Database)
• Proximity to urban areas (GAP land cover)
• Projected urbanization (Terando et al. 2014)
• Human modification (Theobald et al. 2012)
• Elevation heterogeneity (National Elevation Database)
14. Phase 1: literature and other sources
• Scientific literature
• Reports
• Wildlife Action Plans
• US Forest Service Tree Atlas for dominant species
Especially for:
• Climate sensitivities
• Non-climate threats like invasive species
• Management concerns
15. Phase 1 Example results for
East Gulf Coastal Plain Near-coast Pine Flatwoods
16.
17. Phase 1 Sensitivity
East Gulf Coastal Plain Near-coast Pine Flatwoods
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Dominant species (longleaf, slash pine, wiregrass) have low sensitivities here.
Fires and hurricanes are important and are sensitive to climate.
Some rare salamanders and other species depend on mesic, periodically saturated soils.
The ecosystem is also sensitive to sea level rise.
18. Phase 1 Exposure
East Gulf Coastal Plain Near-coast Pine Flatwoods
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Phase 1 Exposure
East Gulf Coastal Plain Near-coast Pine Flatwoods
20. Phase 1 Exposure
East Gulf Coastal Plain Near-coast Pine Flatwoods
For most seasons, time periods and scenarios,
conditions could become hotter and drier.
The water table could become lower, especially
during dry periods (Lu et al. 2009).
Wildfires could become more common or more
intense, but there is uncertainty and debate about
this.
Between 1% and 8% of the ecosystem may be
directly inundated by sea level rise, and 2-3% could
change vegetation type.
Hurricane intensity is projected to increase, leading
to overstory tree mortality, especially on older,
unburned sites.
Longleaf and slash pine are not projected to change
in importance (US Forest Service Tree Atlas).
21. Phase 1 Adaptive Capacity
East Gulf Coastal Plain Near-coast Pine Flatwoods
Recent fire suppression is a major threat.
Relatively small average patch size (0.9 ha)
Occurs fairly close to development, likely placing
more constraints on management.
6% projected to be developed by 2050, 12% by
2100
Invasive species such as cogongrass are
problems.
But…
Species in this system occur in other adjacent
systems.
High degree of protection: over 50% is
protected currently.
0%
10%
20%
30%
40%
50%
60%
Proportionofecologicalsystemextent
Protected Developed Developed
2050 2100
22. Phase 1 Overall vulnerability
East Gulf Coastal Plain Near-coast Pine Flatwoods
Moderate
Some sensitivity and exposure, especially to changes in
fires, hurricanes, hydrology, and sea level.
Substantial adaptive capacity.
23. Phase 1 Example results for
Nashville Basin Limestone Glade and Woodland
24. Flat Rock Cedar Glades and Barrens, TN, Credit: Alan Cressler
25. Phase 1 Sensitivity, Exposure, Adaptive Capacity
Nashville Basin Limestone Glade and Woodland
Sensitivity:
• Seasonal extremes in moisture, and longer term drought, often in late summer and fall
• Many plant species tolerate abiotic stress
• Woody invasion into grasslands slows under drought
Exposure:
• Temperature increases, especially minimum temps.
• Precipitation projections more uncertain
• Could lead to more droughts
• Changes in hydrology uncertain
Adaptive Capacity:
• Limited geographic distribution and restricted to unique edaphic conditions
• Threatened by conversion to human land uses, especially in
Nashville-Murfreesboro area
Vulnerability: High due to low adaptive capacity and potential changes in drought and
hydrology.
26. Phase 1 Example results for
Caribbean Montane Wet Elfin Forest
28. Phase 1 Sensitivity, Exposure, Adaptive Capacity
Caribbean Montane Wet Elfin Forest
Sensitivity:
• Climate conditions are extreme: constant cloud cover, high precipitation.
• Vegetation structure and composition depend on precipitation and orographic effects.
• Periodic hurricanes cause disturbance, affect precip and decrease cloud cover.
Exposure:
• Puerto Rico is likely to warm faster than other places.
• Precipitation projections more uncertain, but on average show a decrease.
• Hurricane frequency likely to increase
• Cloud cover may decrease as a result of these changes.
Adaptive Capacity:
• The distribution at the tops of mountains means lower capacity to adapt.
• Unique species assemblage with many endemics means lower adaptive capacity as well.
Vulnerability: High - high sensitivity to changes in temperature and precipitation, and likely
high exposure to those changes. Distribution at high elevations constrains adaptive
capacity.
29.
30. Phase 2 Assessment Approach: HCCVI for two ecosystems
Adapted from Comer et al. 2012
31. Phase 2: HCCVI
Two ecosystems:
East Gulf Coastal Plain Near-Coast Pine Flatwoods
Nashville Basin Limestone Glade and Woodland
Two time periods:
Mid-century (c. 2050)
Late century (c. 2100)
Minimum and maximum values for input metrics when applicable
from alternative emissions scenarios or other uncertainty.
32. Phase 2: Calculation of climate stress index
The degree to which climate will change in the future within an ecosystem’s current
range.
Compared recent (1980-1999) climate data (Maurer et al. 2002)
with projected data (K. Hayhoe) for each ecosystem.
Monthly minimum and maximum temperature, precipitation: 36 variables
For each variable at each climate data pixel:
Does the projected value exceed the recent value +/- 2 stdev.?
Climate stress index:
1 – proportion of 36 variables that exceed recent value +/- 2 stdev.
Average across pixels in the ecosystem.
34. Climate stress
index
Pine Mid C. min. 0.85
Flatwoods Mid C. max. 0.75
Late C. min. 0.75
Late C. max. 0.55
Nashville Mid C. min. 0.88
Basin Mid C. max. 0.78
Late C. min. 0.77
Late C. max. 0.51
35. Phase 2: Calculation of envelope shift index
The degree to which the suitable climate envelope will change.
Define the current climate envelope using MaxEnt and map to the current
landscape.
Project where that envelope will occur in the future under alternate scenarios.
Envelope shift index: Average suitability score for the ecosystem’s current extent.
36. East Gulf Coastal Plain Near-Coast Pine Flatwoods
Observed
B1
A2
A1FI
Mid-century
37. East Gulf Coastal Plain Near-Coast Pine Flatwoods
Observed
B1
A2
A1FI
End of century
38. Envelope shift
index
Pine Mid C. min. 0.81
Flatwoods Mid C. max. 0.63
Late C. min. 0.54
Late C. max. 0.25
Nashville Mid C. min. NA
Basin Mid C. max. NA
Late C. min. NA
Late C. max. NA
39. Phase 2 Assessment Approach: HCCVI for two ecosystems
Adapted from Comer et al. 2012
40. System Period Sensitivity Indirect
Effects
Adaptive
Capacity
Resilience Vulnerability
Pine Mid C. min. 0.74 0.79 0.50 0.64 Low
Flatwoods Mid C. max. 0.65 0.77 0.42 0.60 Moderate
Late C. min. 0.65 0.79 0.42 0.61 Moderate
Late C. max. 0.50 0.77 0.37 0.57 Moderate
Nashville Mid C. min. 0.55 0.70 0.45 0.57 Moderate
Basin Mid C. max. 0.49 0.66 0.37 0.52 High
Late C. min. 0.49 0.70 0.37 0.53 High
Late C. max. 0.36 0.66 0.32 0.49 Very High
Phase 2: HCCVI Vulnerability Scores
42. Assessing vulnerability:
Summary and future needs
Both approaches gave relatively similar vulnerability ratings for the two ecosystems
Each approach has advantages:
• Phase 1 approach was able to incorporate a wider variety of information and provide
more nuanced assessment
• Phase 2 approach produced quantitative scores that could be compared to one another
Need to incorporate:
• Species interactions
• Feedbacks and interactions among vulnerability components
Need to consider:
• Individual responses to climate change: ecosystems will not likely change as a unit
• Assessing vulnerability for ecosystems is more complex than for species
• The desired future condition
• Is our focus on major species and ecological processes reasonable?
43. Sources of uncertainty and future research needs
• Potential change in precipitation
• Effects of climate on cloud cover (for Caribbean Elfin
Woodlands)
• Impacts on hydrologic regime
• Impacts on disturbance regimes
• Future of biotic interactions, tropic relationships, dispersal
under climate change
Assessing vulnerability will be important to do for a wider
number of ecosystems in the Southeast.
44. Thank you!
Collaborators/Partners:
Jaime Collazo, Matthew Rubino, NC State, Coop. Fish and Wildlife Research Unit
Scott Beck, NC State
Milo Pyne, Rickie White, NatureServe
Adam Terando, USGS Southeast Climate Science Center
Bill Wolfe, Jennifer Cartwright, USGS TN
Bill Gould, USDA Forest Service
Funding:
Southeast Climate Science Center
USGS Gap Analysis Program
Contact me with questions or for a copy of our draft report:
jennifer_costanza@ncsu.edu
Editor's Notes
Identify, quantify, or evaluate the degree to which natural resources or other values are likely to be affected by changing climatic conditions
Sensitivity: inherent traits of a species or system
Exposure: degree to which important climate change variables are likely to change in the future
Adaptive Capacity: Degree to which a system can adjust to changes in the future – depends on inherent characteristics, but also can be affected by management