FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics...
-
Upload
eustace-powers -
Category
Documents
-
view
217 -
download
0
Transcript of FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics...
![Page 1: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/1.jpg)
FireBGCv2:A research simulation
platform for exploring fire, vegetation, and climate
dynamicsRobert Keane
Missoula Fire Sciences LaboratoryRocky Mountain Research StationUSDA Forest Service
![Page 2: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/2.jpg)
Natural Resources Canada
![Page 3: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/3.jpg)
Mo
ritz
M. A
. e
t.a
l. 2
00
5.
PN
AS
;10
2:1
79
12
-17
91
7
Multi-scale controls on fire
Field and empirical s
tudies become more diffi
cult
![Page 4: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/4.jpg)
So much to simulate… What model?
The best models to explore climate change dynamics integrate complex ecological processes over spatial and temporal scales
– Complex interactions at fine scales eventually become manifest at coarse scales
– Models without these interactions have limited application
– Interactions should be across processes & scales
The best models to explore climate change dynamics integrate complex ecological processes over spatial and temporal scales
– Complex interactions at fine scales eventually become manifest at coarse scales
– Models without these interactions have limited application
– Interactions should be across processes & scales
![Page 5: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/5.jpg)
• Mechanistic, spatially explicit individual tree succession model– Ecosystem process
simulation– Fire ignition and
spread– Multi-species /
multi-age stand dynamics
– Operates at multiple spatial and temporal scales
– Captures climate-fire-vegetation interactions
Landscape
Site
Stand
SpeciesTree
The FireBGCv2 model
Simulation platform
![Page 6: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/6.jpg)
FireBGCv2 is NOT…• A prognostic, predictive model
– A model that predicts events– A model that is used for short-term predictions
• Accurate– Complexity increases uncertainty
• Stable– Highly complex models are inherently unstable
![Page 7: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/7.jpg)
FireBGCv2 is…• A regime or cumulative effects model
– Simulates long-term ecological effects– Simulates complex interactions across scales– Simulates many disturbances
• Robust– Mechanistic architecture allows wide application
• A research platform– Explore new landscape behaviors– Compare various modeling approaches
![Page 8: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/8.jpg)
H2OTRANS
DAYTRANS
FOREST-BGC
BIOME-BGC
JABOWA SILVA FIRESUM
FireBGCv2
FIRE-BGC
Stand level gap phase models
“Big Leaf” BioGeoChemical Models
The Lineage or “Family Tree” of FireBGCv2
![Page 9: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/9.jpg)
Key Levels of Organization:
FIRE-BGC Simulation Design
LANDSCAPE
SITE
STANDS (Plot)
SPECIES
TREES
![Page 10: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/10.jpg)
Landscape● Seed dispersal● Cone crops● Fire dynamics:
Ignition Spread● Insect and disease occurrence
White pine blister rustMountain pine beetle
● Management action planning
FIRE-BGC Simulation ModelingProcesses Simulated at Each Scale
● Climate change
● Hydrology
![Page 11: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/11.jpg)
Site● Weather
● Phenology
● Soils
FIRE-BGC Simulation ModelingProcesses Simulated at Each Scale
![Page 12: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/12.jpg)
StandMost important ecologicalprocesses are simulated at this scale
FIRE-BGC Simulation ModelingProcesses Simulated at Each Scale
![Page 13: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/13.jpg)
FireBGCv2 Stand Components
![Page 14: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/14.jpg)
Stand Level Processes Flow Chart
![Page 15: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/15.jpg)
Fire Effects simulated in FireBGCv2
Stand level
![Page 16: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/16.jpg)
• Various management actions– Prescribed burn– Timber harvesting (thinningclearcut)– Wildland fire use
• Grazing• Wildlife habitat suitability• Hydrology• Stream temperature
Management ActionsStand Level
![Page 17: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/17.jpg)
Species● Regeneration
● Phenology
● Fire effects
FIRE-BGC Simulation ModelingProcesses Simulated at Each Scale
![Page 18: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/18.jpg)
Tree● Growth
● Mortality
● Regeneration
● Litterfall
● Wildlife habitat
● Snag dynamics
FIRE-BGC Simulation ModelingProcesses Simulated at Each Scale
![Page 19: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/19.jpg)
Dynamic Output
● Tabular and map output available
● Over 890 possible output variables for tabular summaries
● Only 25 map variables
FIRE-BGC Simulation Modeling
● Output by landscape, site, stand, species, tree
![Page 20: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/20.jpg)
![Page 21: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/21.jpg)
– Six temperature factors: 1 °C - 6 °C
– Seven precipitation factors: 70% - 130%
– Ecosystem and fire effects
– How much change is too much?
Modeling tipping points
WARMER
DRIER
![Page 22: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/22.jpg)
Glacier NP Yellowstone NP Bitterroot NF
Fire rotation (yrs)
WARMER
DRIER
025
50
Kilom
eters
169 yrs. 223 yrs. 56 yrs.
![Page 23: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/23.jpg)
Glacier NP Yellowstone NP Bitterroot NF
Tree mortality (%)
WARMER
DRIER
025
50
Kilom
eters
59.7% 70.3% 17.0%
![Page 24: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/24.jpg)
Glacier NP Yellowstone NP Bitterroot NF
Basal area (m2/ha)
WARMER
DRIER
025
50
Kilom
eters
38.8 m2/ha 26.5 m2/ha 29.6 m2/ha
![Page 25: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/25.jpg)
WARMER
DRIER
Glacier NP Yellowstone NP Bitterroot NF
Basal area thresholdsSignificant (P < 0.5) changes in mean basal area for climate change scenarios for MD-GNP, CP-YNP, and EFBR. Solid fill indicates decreased basal area and hatched fill indicates increased basal area as compared with the no climate change scenario.
1° 2° 3° 4° 5° 6°
130%
120%
110%
100%
90%
80%
70%
![Page 26: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/26.jpg)
Dominant species changes
Lodgepole pine Douglas-fir
Yellowstone NP
![Page 27: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/27.jpg)
Current Climate Climate & FireClimate does not affect forest
Climate creates new forest composition or structure
Climate creates vegetation transition
Hypothesized Change
Same Forest
New Forest
Grassland
Sage Steppe
Grassland
Sage SteppeFire Adapted New Forest
Fire Adapted New Forest
New ForestCurrent Forest
Grassland
Same Forest
![Page 28: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/28.jpg)
Climate
Photo: US NPS
Douglas-fi
r
Lodge
pole Pine
Engelm
ann Sp
ruce
Non-Forest
White
bark Pine
Subalpine Fi
r
A2
B1
Historic
Percent CoverSame Forest
New Forest
Grass
Sage
Grass
SageFire Adapted
Fire Adapted
New Forest
Current Forest
Grass
Same Forest
New Forest
Same Forest
![Page 29: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/29.jpg)
All Fires Historical B1 A2
Fire Rotation 320 y 150 y 120 y
Mean Annual Area Burned 483 ha 853 ha 1328 ha
Climate + Fire
Percent Cover
A2
B1
Historic
Douglas-fi
r
Lodge
pole Pine
Engelm
ann Sp
ruce
Non-Forest
White
bark Pine
Subalpine Fi
r
Same Forest
New Forest
Grass
Sage
Grass
SageFire Adapted
Fire Adapted
New Forest
Grass
Same Forest
Current Forest
Grass
Sage
Grass
Same ForestSame
Forest
![Page 30: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/30.jpg)
Management
Photo: US NPS
Douglas-fi
r
Lodge
pole Pine
Engelm
ann Sp
ruce
Non-Forest
White
bark Pine
Subalpine Fi
r
0% Suppression
50%
100%
Percent CoverSame Forest
New Forest
Grass
Sage
Grass
SageFire Adapted
Fire Adapted
New Forest
Current Forest
Grass
Same Forest
Grass
SageFire Adapted
New Forest
![Page 31: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/31.jpg)
FireBGCv2 Limitations• Difficult to parameterize• Difficult to initialize• Long execution times (20-50 hours)• Extensive memory requirements (>7 GB)• Abundant output• Difficult to understand and use• Long training time• Not really a management model
![Page 32: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/32.jpg)
FireBGCv2 Advantages• One of the most comprehensive
landscape models available• Highly complex, non-linear behaviors• Fire-climate-vegetation linkage• Runs on any computer• Extensive documentation• Code available• Flexible structure
![Page 33: FireBGCv2: A research simulation platform for exploring fire, vegetation, and climate dynamics Robert Keane Missoula Fire Sciences Laboratory Rocky Mountain.](https://reader037.fdocuments.in/reader037/viewer/2022103006/56649e615503460f94b5be5c/html5/thumbnails/33.jpg)
Final FireBGCv2 Information• Coded in C programming language• Compiles on any platform• Web site: • http://www.firelab.org/research-projects/fire-ecology/139-firebgc
• Implemented for 14 landscapes• Used in over 15 projects…