1. Can global models reproduce the current increase in western US wildfires and project a reliable future trend?
Dominique Bachelet, Conservation Biology Institute
Dave Conklin, Dept Biological and Ecological Engineering, Oregon State University
Brendan Rogers and Maureen McGlinchy, Oregon State University
Jim Lenihan, Ron Neilson, and Ray Drapek, PNW U.S. Forest Service

2. Why is it important?
Fire causes change in albedo, so affects climate
Fire can cause vegetation shifts
Fire causes change in C stocks and sequestration potential
important to be able to understand, simulate and project

3. Outline
MC1 fire model
Fire events in western US during the last decade
Climate indices, fire and model results
PDO and PNW, CA fires
El Niño and PNW, CA fires
Strengths and limitations of fire model
Simulated fires respond to climate cycles in climate input data
Strong climate signal overwhelms human impacts
Carbon sequestration linked to climate and fire

4. MC1 Dynamic General Vegetation Model
James Lenihan, Dominique Bachelet, Chris Daly, Ron Neilson (USFS and OSU)
BIOGEOGRAPHY
BIOGEOCHEMISTRY
LIFEFORM COMPOSITION
LIVE BIOMASS
CLIMATE
LIVE/DEAD
BIOMASS
REDUCTION
NUTRIENT
LOSS
FIRE
LIVE/DEAD BIOMASS
SOIL MOISTURE
LIFEFORM COMPOSITION
VEGETATION STRUCTURE

5. Fire Module Fire area and behavior Fire effects Mortality Biomass
Current
Aboveground
Carbon Pools
Current
Vegetation
Type
Current
Weather
Current Soil
Moisture
Fuel Loading
Crown Structure
Live and Dead
Fuel Moisture
Fire area and behavior
Fire effects
Mortality
Biomass
Consumption
Emissions
Nutrient
Loss
Fire Module

6. Outside the historical
from Schoenagel et al. 2004
Canada
11 Western States
Arizona and New Mexico
Observed upward
trend in wildfires
in North America ?
by American Forest Resource Council
Outside the historical
range of variation?

7. Pacific Decadal Oscillation (Mantua et al. 1997) and fires
North Pacific monthly sea surface temperature variability
Active suppression
fuel accumulation
Post-settlement fires
Increase in fires
Warm PDO
Cool PDO
Warm PDO
Source: Jeremy Littell et al Climate and wildfire area burned in western US ecoprovinces, Ecological Applications.

8. Effects of PDO on Winter Precipitation
Positive (warm) PDO
dry
wet
fuel
build-up
dry fuels
Standardized Precipitation Anomaly
Negative (cool) PDO
Standardized Precipitation Anomaly
wet
dry
source: George Taylor, Corvallis

9. Pacific Decadal Oscillation and PNW fires
Years with fires > 80,000 ha between 1916 and 1997 in National Forests
source: Mote et al. 1999

10. Dynamic Global Vegetation Model MC1 Results at 3 spatial grains
for the state of California

11. Dynamic Global Vegetation Model MC1 Results at 3 spatial grains
Oregon and Washington ?

12. ENSO and fires (Westerling and Swetnam 2006)
Credit: Tom Swetnam and Julio Betancourt. Updated from Swetnam, T.W., and J.L. Betancourt, 1990: Fire-Southern Oscillation relations in the southwestern United States. Science 249:

13. Effects of El Nino on Winter Precipitation and Temperature
fine fuel
build-up for
La Nina fires
drought
set-up
(reduced
snowpack
longer
fire season)
source: G. Taylor, Corvallis

14. La Nina
1973
1988
El Nino
2002
1987
1975
1998
1972
1997
1965
1982
2002
1987
strong El Nino years:
, , ,
La Nina years:
, , ,

15. Strengths and limitations of fire models

16. There are clear cycles in time series of fire and carbon: climate inputs matter
Strong climate signal overwhelms human impacts: simulations match observations
Carbon sequestration linked to climate and fire

17. Dynamic Global Vegetation Model MC1 run at 3 spatial scales - CA
Connection
with climate
index at the coarser
scale

18. Dynamic Global Vegetation Model MC1 run at 3 spatial scales- OR&WA
Similar dynamics at all scales
No obvious link to climate index

19. Dynamics show clear cycles: drought of the 1930s,
signal in the early 1970s
and 1990s (La Nina?)
strong El Nino years:
, , ,
La Nina years:
, , ,

20. Observed vs Simulated Area Burned on Western USA Federal Lands 1916-2000
in million ha
Observations:
MC1 simulation at 8km, Lenihan

22. Simulated fires respond to climate cycles in climate input data: scale matters
Strong climate signal can overwhelm human impacts but human actions may affect future fire regimes
Carbon sequestration linked to climate and fire

23. Ignition limited (wet) Fuel limited SUPPRESSION IMPACT
boreal, subalpine, tropical rain forests
woodlands,
high elevation forests
INVASIVES
FIRE SUPPRESSION
IMPACT
RAIN
Fuel limited
low elevation dry forests, savannas
DROUGHT
SUPPRESSION
IMPACT
source: Meyn et al. 2007
Progress in Physical Geography 31:
(LIF=large intense fires)

24. Simulated fires respond to climate cycles in climate input data: scale matters
Strong climate signal overwhelms human impacts but human actions may affect future fire regimes
Carbon sequestration linked to climate and fire

25. vegetation dieback and/or soil carbon depletion
Response
to climate
signal:
interannual
variations
in C stocks
vegetation dieback and/or soil carbon depletion
warm
wet
hot
dry
cool
dry
hot
dry
wet
cool
wet
cool
wet
cool * *
SOIL
GAIN
LOSSES
Yosemite NP
Conklin unpubl.

26. 1: what is fixed in a year is entirely released as fire emissions
Fraction of Net Primary Production consumed by fire
1: what is fixed in a year is entirely released as fire emissions
CSIRO B1
HADLEY A1B
MIROC A2
source: Dave Conklin, unpub.

27. Thank you for your attention!
Olympics Mountains, WA
Thank you for your attention!