Post on 05-Jan-2016
description
Fire regime• The nature of fires occurring over an
extended period of time
• General, long-term pattern of recurring fires over a particular time and place
• Typically includes frequency and severity
• Ideally includes size, spatial pattern, season, and variability
Describing fire regimes• Frequency: how often, usually characterized
as interval in years between fires• Extent: typical size• Magnitude:
• Intensity • Severity
• Rotation• Seasonality• Predictability • Spatial patterns
Fire frequency• Point frequency
• Fire return interval• Weibull mean fire interval• Probability of occurrence
• Area frequency both express the length of time necessary to burn an area equivalent to the study area• Rotation • Fire cycle is calculated based on the distribution
of ages in a time-since-fire map • Number of fires in a given area
Quantifying fire regimes: point fire frequency
• Measures• Mean fire interval (Heinselman 1973, Agee 1993)• Wiebull mean fire interval (Johnson 1992, Finney
1995, Grissino-Meyer 1999)
• Explicitly spatial, but represent spatial patterns as aggregates of point samples
Fire severity: degree of ecosystem change• Tree mortality • Heat penetration into the soil (Lea and Morgan
1993)• Degree to which fires consume organic biomass on
and within the soil (Lenihan et al. 1998)• Change in color of ash and soil (Wells et al. 1979,
Ryan and Noste 1985)• Combination of fire effects (Turner et al. 1994)
Fire intensity• Physical description of fire behavior
• Defined as the amount of energy released by a flaming front
• Closely correlated with flame length (Albini 1976)
Understanding fire regimes across spatial and temporal scales is challenging
• Fire is a stochastic, spatially complex disturbance process
• Data are from points or from small areas and often from relatively short time series
• Extrapolation is difficult
• Interpretations are often biased by truncated time series (Finney 1995), which causes us to overestimate fire frequency.
Understanding fire regimes across spatial and temporal scales is challenging
• Climate, vegetation, and topography all interact with fire
• Legacy of past events varies
• Fire and fire effects are inherently variable and heterogeneous
• Fire regimes are not static
Errors• Imperfect recording of fire events
• Not all fires scar trees• Subsequent fires may consume evidence
• Sampling may not detect all fires
• Heterogeneity and variability
• Autocorrelation in time and space
Frequent, light surface fires (2)
Infrequent, light surface fires (1)
Infrequent, severe surface fires (3)
Short-return interval, crown fires (4)
Very long-return interval, crown fires (6)
Long-return interval, crown fires (5)
Frequent, low-intensity surface fires (1)
Infrequent, low-intensity surface fires (2)
Infrequent, high-intensity surface fires (3)
Short-return interval, stand-replacement fires (4)
Very long-return interval, stand-replacement fires (6)
Variable: Frequent, low-intensity surface & long-return interval stand-replacement fires (5)
Heinselman Kilgore Flora Volume Hardy et al. Morgan et al.
No natural fires (0)
Understory fires, (forest)
Stand replacement fires (forest & grasslands)
Variable or mixed fires (forest)
Non fire regimes
<35 yr. Low Severity fires (forest)
<35 yr. Stand-replacement fires (forest & grassland)
35-100+ yr. Stand replacement fires (forest & grassland)
200+ yr. Stand replacement fires (forest)
35-100+ yr. Mixed severity fires (forest)
No burn
Nonlethal fires (forest)
Nonlethal fires (grassland)
Stand replacement fires (forest)
Mixed fires (forest)
Rarely burns
Why map fire regimes?• Assessment and planning
• Contrasting past to present
• Modeling
• Understanding the influence of climate, topography, and vegetation
• Identifying gaps in knowledge
Departures• Changes in fire intervals can be used to
prioritize fire and fuels management based upon “ecological need” (Caprio et al. 1997)
• http://www.nps.gov/seki/fire/frid97.htm
Departures• Fire Return Interval Departure = (RImax - TSLF)/RImax
• RImax = maximum average return interval for vegetation class
• TSLF = time since last fire, yrs• Moderate (0 to –2), high (-2 to –5), and extreme (> -5)
Fire Regime Condition Class
• Condition classes (relative to historical fire intervals)• I: No significant departure (<1 fire interval)• II: Moderate departure in fire freq. (>1 interval)• III: Significantly altered fire freq. (by multiple
intervals) and vegetation from historical range• In condition class III, critical ecosystem elements
may be lost when fires occur. In all condition classes vegetation composition and structure has changed, more for condition class II and the most for condition class III.
Historical Fire Regimes of the United StatesVersion 2.0 Version 1.0
Legend
0-35 yr. frequency, Non-lethal Severity0-35 yr. frequency, Stand Replacement Severity35-100+ yr. frequency, Mixed Severity35-100+ yr. frequency, Stand Replacement Severity
200+ yr. frequency, Stand Replacement SeverityAgriculture (Only Version 1.0)
WaterBarren http://www.fs.fed.us/fire/fuelman
http://www.fs.fed.us/fire/fuelman
Fire history methods
Natural archives of fire history data • Dated fire scars in tree rings: yr and season
• Time-since-fire maps reconstructed from ages of trees, usually from even-aged stands burned in stand-replacing fires
• Charcoal from sediment in lakes and bogs
• Networks of precisely dated fire-scar samples and sites have been used to estimate area burned based upon the proportion of sites scarred in a given year
Fire history from fire-scarred trees• Multiple fire scars from
single trees and groups of trees
• Works best for surface fires that burned relatively frequently
• Cross-date to identify exact year of scar
• Prepare surface and magnify to identify season of fire. This is done by examining the cells damaged by fire
Dated fire scars on trees• Low severity fires
• Some trees survive
• Part of cambium is killed
• Crossdate fire scars using dendrochronology (http://web.utk.edu/~grissino/)
• Composite dates from multiple individual trees
• Calculate fire frequency from distribution of intervals between fires
Strengths of fire-scar data• Extraordinary time depth -- typically 300 to 500
years, and more than 2,000 years in giant sequoia (Swetnam 1993)• Long records encompass extreme events
• High temporal resolution: fires are dated to the year, and often season, of occurrence
• When accurately dated it is possible to correlate fire events across spatial scales, and to compare the highly synchronized events (or asynchronous events) with independent temporal and spatial data
• Can infer other things: climate, suppression-release
Limitations• We know more about fire frequency than fire size,
severity, rotation, variability, and other characteristics of fire regimes
• Accuracy and precision of fire history data are seldom quantified
• Variability of fire regime characteristics over time and space is seldom evaluated
• Few fire history data available for grasslands, shrublands and woodlands
Fire history from mixed and stand-replacing fires
• Stand age reconstruction
• Time-since-fire maps
Time-since-fire maps• Stand-replacing fires• Even-aged cohorts of trees
established post-fire • Assume patch age-class
distribution is relatively stable over time (steady-state shifting mosaic)
• Assume frequency of disturbance is spatially homogeneous, stationary Poisson process
• If small, old stands are not detected or aged accurately, the frequency of disturbance is overestimated
Human archives • Operational databases of fire occurrence• Atlases: maps of fire perimeters and locations • Remotely sensed fire location, perimeter and
severity • Interviews, personal diaries, or literature searches• Land survey records • Aerial photographs • The National Interagency Fire Management
Integrated Database (NIFMID)
Fire atlases• Compilations of mapped fire perimeters• Paper or digital• Include date and perimeter of fires, but typically do
not include information on fire severity, rate of spread, or perimeters of small fires
• Only larger fires (>50 or 100 ac) are included, but they likely to represent a large proportion of area burned
• Errors in spatial location and date of fire occurrence are difficult to assess, likely vary through time and and can be severely limiting
Fire atlases• Perimeters often only approximate
• Spatial pattern of burned areas within the mapped perimeters is seldom known
• Can do spatial analyses of fire location, area burned through time, and frequency
• Typically only larger fires are mapped
• Accuracy likely varies through time
• Accuracy has not been assessed
Fire atlas boundary
Gila NF W ilderness DistrictBoundary
1900
1910
1920
1930
1940
1950
1960
1970
1980
1990
20 -Century Fire Perimeters -- G ila/Aldo Leopold Wilderness AreasNew Mexico
th
AZ NM
N
Rollins/LTRR
20 k
Fire frequency from fire atlases
• “Wall-to-wall”• Example is from the
Gila/Aldo Leopold Wilderness complex in New Mexico and the Selway-Bitterroot Wilderness Area in Idaho and Montana
• In this example, only fires >50 ha in size are included
U n b u rn ed
B u rn e d O n c e
B u rn e d Tw ic e
B u rn e d T h ree o r M o re T im e s
20 k
N
GALW C
SBWA
Aerial photographs• Fire perimeter, size, location, severity, pattern
• One of the few sources of fire severity information other than detailed field sampling during or immediately after a fire
NIFMID• National Interagency Fire Management
Integrated Database
• Includes all fires by size class, location, and cause, but only for recent decades
• Individual fires are represented as points (not necessarily the ignition point), size class, whether human or lightning ignited
• Includes small fires, and thus can complement fire atlases and other databases
Remote sensing from planes or satellites
• Not used extensively
• Great potential for mapping post-fire tree mortality and severity
• Lightning occurrence
Fire History Data SourcesTemporal Scale Spatial Scale
Atlases 20th CenturyYear
Entire wilderness area,1:24,000
Time Series of Aerial Photos
1930s to presentYear
Selway-River Basin1:24,000
NIFMID FireReport Data
1974-1997Year, month and day
Point data
Dendroecol.Data
Multi-century Year and season
Points within basins30m DEM
Fire History Data SourcesStrengths Limitations
Atlases 1. Fire date and location 2. Large fires (>50 ha) only
1. Accuracy varies2. Only perimeters
Time Series of Aerial Photos
1. Fire date, perimeter, and severity
2. Fine-scale
1. ‘Lab’ intensive2. New technique
NIFMID FireReport Data
1. Date, location, and size class of all fires
2. Ignition source
1. Point data2. Limited: 1976-1996
Cross-dated fire scars in tree rings
1. Fire date and season2. Spatial location3. Multiple centuries
1. Point data2. ‘Lab’ intensive
Example of using multiple data sets• Compare and contrast fire patterns in two
areas• Selway-Bitterroot Wilderness Area (Idaho and
Montana)• Gila/Aldo Leopold Wilderness Complex (New
Mexico)
• What are the fire patterns through time?
• How are fire patterns related to topography, fire management policy, and to drought?
• From: Rollins et al. 2000
Study areas• SBWA
• 547,370 ha• 500 m to 1500 m
• GALWC• 486,673 ha• 1300 m to 1500 m
Developed lands
W estern redcedar
Grand firDouglas-fir
Lower subalpine
Persistent herblands
Upper subalpine
Rock/alpine
Water
n
Desert-scrub-grass
Douglas-fir
M ixed conifer
Pi on--oak-juniperñ
Ponderosa pine
Riparian
Spruce/fir
20 k
Selway-B itterrootW lderness Area
Gila/Aldo Leopold W ilderness Com plex
500 k
M oggollon M ountins
Area burned• Selway-Bitterroot Wilderness Area
• 474,237 ha burned in 437 fires from 1880 to 1996• 7 yrs of extensive fire, 72% of all area burned• 1889, 1910, 1919, 1929, 1934, and 1988
• Gila-Aldo Leopold Wilderness Complex• 147,356 ha burned in 232 fires from 1909 to 1993• 6 yrs of extensive fire, 71% of all area burned• 1909, 1946, 1951, 1985, 1992, 1993
Area burned during three different eras of fire management
Area burned and Palmer Drought Severity Index (PDSI)
Area burned by fire management eraArea burned (ha) % of study area Fire rotation (yr)
Selway-Bitterroot
1880-1935 482,030 60.9 92
1936-1974 9,622 1.2 3206
1975-1994 58,427 7.4 271
Gila/Aldo Leopold
1880-1946 32,601 6.7 552
1947-1974 34,742 7.1 406
1975-1993 80,424 16.5 114
Fire rotations (yr)Selway-Bitterroot Wilderness Area
All years1880-1996
Early1880-1934
Fire control1935-1975
Fire manage.1976-1996
W. Redcedar 368 41 396,498 359
Herblands 80 79 4,167 77
Grand fir 384 66 7,380 267
Douglas-fir 169 104 4,704 140
Lower subalpine
519 117 3,651 230
Upper subalpine
852 191 3,361 361
Rock/alpine 371 295 1,957 164
Fire rotations (yr)Gila-Aldo Leopold Wilderness Area
All years1909-1993
Early1909-1946
Fire control1947-1975
Fire manage.1976-1993
Desert scrub-grassland
15,573 120,514 40,782 4,324
Pinyon-oak-juniper
540 1,156 1,182 188
Ponderosa pine
200 382 410 74
Douglas-fir 180 353 205 84
Mixed conifer 245 612 145 207
Spruce-fir 537 508 435 998
Fire frequency by potential vegetation type (PVT)
Topography• 30 m DEMs• Level I and II
500 k
Gila/Aldo Leopold Wilderness Com plex
Selway-BitterrootWilderness Area
20k
Elevation Slope Aspect
Elevation
Slope
Aspect
N
Are fire patterns independent of elevation?
Fire frequencies and landscape characteristics: K-S two-sided probabilities
GALWC SBWA
Elev. Aspect Slope Insol. Elev. Aspect Slope Insol.
Unburned 0.43 1.00 1.00 1.00 0.00 0.82 0.97 1.00
Once 0.00 0.82 1.00 0.99 0.00 1.00 0.97 1.00
Twice 0.00 0.70 0.99 0.77 0.00 1.00 0.30 1.00
Three 0.00 0.99 0.13 0.04 0.00 0.70 0.22 0.48
Logistic regression models
2
Model Variable Coefficient T-ratio
Gila Wilderness
Area
Intercept -6.092 -20.92
Elevation 0.002 13.63
Slope 0.012 3.13
Distance From NE -0.029 -4.00
PCE = 82% = 0.043
2
Model Variable Coefficient T-Ratio
Selway-Bitterroot
Wilderness Area
Intercept 0.938 5.75
Elevation -0.002 -25.68
Slope 0.012 3.56
Distance From NE 0.20 2.99
PCE = 87% = 0.103
McFadden’s
McFadden’s
What is the fire evidence from lake sediments – Burnt Knob Lake
• ~4 m of sediment, pollen and charcoal • Recent deposition rate of 0.08 cm/yr or 12.23
years/cm• Periods of high fire activity occur between 13,000
and 11,500 14C yr B.P. and at ca. 6000, and 2250 14C yr B.P.
• Severe, probably stand-replacing fires occurred at ~13,000 14C yr B.P., ~12,000 14C yr B.P., and ~6000 14C yr B.P.
Fire history• 12 fire years in Burnt Knob Lake basin
between 1580 and 1883 based on dated fire scars in tree rings
• Charcoal peaks in lake sediments match fire events in AD 1900/1904, 1883, and 1838
• No evidence of 1910 fire in lake sediments, fire scars, or fire atlases
Age structure• Lodgepole pine and whitebark pine establish
very quickly following fire
• Many large diameter whitebark pines survive fires that are lethal to many surrounding trees
• Some pulses of regeneration are not related to fires
Climate from tree rings• Chronology spans the period 1197-1996, with
good sample depth from 1400-1996
• Based upon 38 series from whitebark pine (29 trees), with an interseries correlation of 0.510 and a mean sensitivity of 0.202
• These trees are more sensitive to temperature than drought
What drives and determines fire patterns across time and space?
• Regional climate entrains fire patterns at fine spatial scales, overriding the influence of local topography and vegetation, leading to synchrony at widely separated sites and across regions
Drivers• Local site productivity
• Topography
• Climate
• Fire exclusion policies
• land use
• Exotic plants
Questions • Why do we understand more about the
temporal patterns of fires than we do about the spatial patterns of fires?
Challenges and limitations• Little empirical data addresses both long time
periods and broad spatial scales, but these are rapidly developing.
New directions• Multiple, integrated data sets
• Climate change
• Fire and lightning
• Insects, drought, climate and fire
• Patterns across time and space
1968
1965
1992
19921938
1953
1989
1904
1953
1904
10
5
9
15
37
5
5
5
Gila/Aldo Leopold Wilderness ComplexMogollon Baldy - Langstroth Mesa Transect
1986 - 1997 fires per 100 ha
Lightning Ignitions
Human Ignitions
Lightning, fires, topography and vegetationGALWC, fires/100 ha,1986 - 1997
Lightning ignitions Human ignitions