Transcript Slide 1

Extension of the forest ecosystem simulation model FORECAST:
incorporating mountain pine beetle, fire, climate change, and wildlife
Hamish Kimmins, Kim Scoular, Brad Seely, Clive Welham, Yueh-Hsin Lo, Brock Simons, Angelica Boldor
Abstract
References
Over the last few years, the mountain pine beetle has shown once again that it is a powerful force of forest
disturbance. Strategies to minimize the negative impacts of this natural disturbance must be developed and
incorporated into forest management plans. However, experience has shown us that for management strategies to be
robust they must be developed within an ecosystem context and projected over relevant time and spatial scales.
FORECAST is a stand-level, hybrid ecosystem management simulation model that acts as the foundation for the
landscape-level simulation programs PFF and LLEMS, and can be used as an ecosystem-based driver of timber supply
(e.g. ATLAS/FPS) and wildlife habitat supply (e.g. SIMFOR) models. The predictive capacity of FORECAST is being
increased through the addition of dynamic mountain pine beetle, fire, climate change, and wildlife habitat suitability
components. Together, these additions will greatly increase the power of FORECAST as a tool for predicting possible
effects of proposed forest management activities within the context of risks of natural disturbance and possible climate
change.
1. Ministry of Water, Land and Air Protection. 2002. Indicators of
Climate Change for British Columbia.
2. Seely, B., P. Arp, and J.P. Kimmins (1997). A forest hydrology
submodel for simulating the effect of stand management and
climate change on water competition and stand water stress. In
Amaro, A. and M. Tome (Eds.), Conference proceedings
"Empirical and process-based models for forest, tree and stand
growth simulation", 21-27 September, 1997, Oeiras, Portugal.
3. Shore, T.L., and L. Safranyik. 1992. Susceptibility and risk rating
systems for the mountain pine beetle in lodgepole pine.
Forestry Canada. Pacific Forestry Centre, Victoria BC.
4. Shore, T.L., L. Safranyik, J.P. Lemieux. 2000. Susceptibility of
lodgepole pine stands to the mountain pine beetle: testing of a
rating system.
Feedback
Mule deer (Odocoileus hemionus)
Photo © John Marriott, www.wildernessprints.com
(Shore et al. 2000)
User-Defined
Habitat Suitability/
Population Demographic
Equations
Coarse Woody
Debris
Snags
Trees
Species
Density
Age
Height
Canopy Depth
Species
Decay State
DBH
Density
Species
Decay State
DBH
Density
User-Defined
Infestation Timing
Loss Prediction Model
Mountain Pine
Beetle
Shore/Safranyik Stand
Susceptibility Index
(Shore and Safranyik,
1992)
Plants
Species
Height
Edible
Biomass
Density
Basal Area
of Pine >15cm
dbh
Total Basal Area
>7.5cm dbh
Age
User-Defined
Location
Mountain Pine Beetle
Stand-Level
Habitat Variables
Habitat
Variables
Wildlife
FORECAST
Pine marten (Martes americana)
Photo © John Marriott, www.wildernessprints.com
Climate Change
Fuel
Variables
Biomass Variables
Soil
Structure
Belowground
Vegetation
Structure
User-Defined
Precipitation Pattern
Overstory
Vegetation
Structure
User-defined
Climate Data
Understory
Vegetation
Structure
Litter
Bryophytes
Plants
Above ground
Below ground
Precipitation
Relative Humidity
 Wind (speed, direction)
Temperature
Tree
Foliage
Branches
Bark
Roots
CWD
Snags
ForWaDy
Hydrological Model
(Seely et al. 1997)
User-Defined
Temperature Change
Actual
Transpiration
Transpiration
Demand
Moisture in
LFH Layers
Fire Module
Fire Severity
Decomposition Rate
Adjustment
Feedback
Transpiration
Deficit Index
a)
Duff
Fire Risk
Fire Impact
Growth Rate
Adjustment
b)
Figure 1 a) Change in Annual Temperature, 1895-1995 (Ministry of Water, Land and Air
Protection, 2002). b) Change in seasonal precipitation, 1929-1998, % per decade (Ministry
of Water, Land and Air Protection, 2002).
Photo by Phil Maranda
Fire