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Transcript
Mt. Graham red squirrel use of forest habitat:
Historical, present, and future perspectives
School of Natural Resources & the Environment
University of Arizona
Tucson, AZ
Final Report for
U.S. Forest Service
Rocky Mountain Research Station
RJVA 08-253
31 January 2014
Christopher D. O’Connor1
John L. Koprowski1
Ann M. Lynch2
Donald A. Falk1
1School
2Rocky
of Natural Resources & the Environment, University of Arizona, Tucson, AZ
Mountain Research Station, US Forest Service, Tucson, AZ
Abstract
Geographically isolated populations of endangered species such as the Mount
Graham red squirrel (MGRS) (Tamiasciurus hudsonicus grahamensis) are particularly
sensitive to fluctuations in habitat quality and extent. In recent decades a series of
insect outbreaks and high-severity fires degraded the sole MGRS habitat in the
Pinaleño Mountains of southeast Arizona, and have raised concerns about the longterm viability of the species. In this study we use dendrochological and spatial analysis
methods to reconstruct the history of MGRS habitat size and quality over the past three
centuries to provide historical context for current habitat conditions. We found that
EuroAmerican land uses starting in the late 1800s excluded fire from the mixed-conifer
forest, resulting in a significant expansion of suitable MGRS habitat over the next
century. Suitable habitat at the start of the MGRS monitoring program in 1989 was
greater than at any time in the reconstructed period. Prior to EuroAmerican settlement,
habitat would have been limited primarily to the spruce-fir forest by the frequency and
severity of fires burning in the mixed-conifer forest at the ecotone between spruce-fir
and mixed-conifer forest types. The spruce-fir and mixed-conifer forests burned in a
large, high-severity fire in 1685, resulting in a much greater reduction in suitable habitat
for MGRS, lasting several decades, than has been experienced by the contemporary
squirrel population. Recovery of the MGRS population following the 1685 fire suggests
that MGRS is highly resilient to significant habitat degradation. Recent disturbances
had the greatest effects on spruce-fir forest and forecasts of future temperature and
precipitation conditions suggest a decline in suitable conditions for this forest type.
Over the past century MGRS populations have adapted to mixed-conifer forest, which
now hosts the majority of active middens and nests. If historically-associated habitat in
the spruce-fir forest continues to decline, the mixed-conifer forest may provide suitable
resources for MGRS if exclusion of fire from these sites continues.
2
Contents
Abstract ...................................................................................................................................... 2
Introduction................................................................................................................................ 4
Study area ............................................................................................................................. 6
Methods ..................................................................................................................................... 7
Forest species demography ............................................................................................... 8
Fire history ............................................................................................................................. 9
Spatial reconstruction of 1685 post-fire forest recolonization ..................................... 10
Midden density surface ..................................................................................................... 10
Spatial reconstruction of fire frequency .......................................................................... 11
Results ..................................................................................................................................... 12
Spruce and corkbark fir recovery following 1685 .......................................................... 15
Midden density surface in relation to fire and forest recolonization ........................... 18
Discussion ............................................................................................................................... 23
MGRS habitat and other forest disturbances ................................................................ 25
Future habitat outlook ........................................................................................................ 26
Literature cited ........................................................................................................................ 28
Supplemental figures ............................................................................................................. 32
3
Introduction
The Mount Graham red squirrel (MGRS) (Tamiasciurus hudsonicus
grahamensis) is a federally listed subspecies endemic to a single mountain range in
southeastern Arizona. Within its home range in the Pinaleño Mountains, MGRS midden
(Smith and Mannan 1994, Merrick et al. 2007) and nest locations are strongly correlated
with dense stands of mature, large diameter conifers with a high proportion of corkbark
fir (Abies lasiocarpa var. arizonica (Hook.) Nutt.). High stand densities limit exposure of
squirrels to aerial predators (Schauffert et al. 2002, Rushton et al. 2006) and mature
stands with abundant corkbark fir are indicators of sites with infrequent fire that provide
abundant seeds (Burns and Honkala 1990) and cool moist conditions and accumulated
coarse woody debris provide appropriate conditions for edible fungi (Harmon et al.
1986) and cone storage (Zugmeyer and Koprowski 2009). Potential MGRS habitat
meeting these conditions exceeded 12,000 ha prior to the 2004 Nuttall-Gibson fire
(Hatten 2000), although, the area used actively by the ~ 300 squirrels was significantly
smaller (Koprowski et al. 2005). Active use of middens by MGRS in mixed-conifer was
equivalent to use in spruce-fir forest prior to 1996. However, after a decade of insect
outbreaks and two mixed-severity fires, MGRS activity decreased markedly in the
spruce fir (Koprowski et al. 2005, Zugmeyer and Koprowski 2009). These disturbances
reduced seed production and created abundant canopy gaps that facilitated predation
by Mexican spotted owl (Strix occidentalis lucida) and other avian predators.
Damage to the spruce-fir forest initiated with an outbreak of an endemic looper
moth (Nepytia janetae Rindge) that caused defoliation to all life stages of spruce and
corkbark fir from 1996 - 1999 (USDA Forest Service 2000). Weakened host defenses
4
likely contributed to subsequent outbreaks of spruce beetle (Dendrochtonus rufipennis
Kirby) and western balsam bark beetle (Dryocoetes confusus Swaine) from beetle
populations that established following a winter ice storm in 1993. Damage to spruce
needles continued with the introduction of spruce aphid (Elatobium abietnum Walker), in
1999 (Lynch 2009). Although N. janetae and spruce aphid can be lethal, the majority of
host tree mortality can be attributed to spruce beetle and western balsam bark beetle
activity (Lynch 2004).
During the N. janetae outbreak from 1996-1999 high numbers of looper larvae
may have served as an additional source of nutrition that increased survivorship of
MGRS (Lynch et al. 2009), resulting in a short-term population increase prior to
declines caused by loss of surviving spruce and corkbark fir. Direct mortality of MGRS
in the 2004 Nuttall-Gibson fire was low (Leonard and Koprowski 2010); however, the
loss of canopy cover and increased exposure to predators as a result of foraging in
insect and fire-created gaps caused a steep decline in MGRS survivorship relative to
less impacted areas after 2002 (Zugmeyer and Koprowski 2009).
The combination of insect outbreaks and fire reduced the extent of spruce-fir
forest by 66% and significantly reduced the area and quality of suitable MGRS habitat
(Koprowski et al. 2005, Zugmeyer and Koprowski 2009). Total MGRS census counts in
December 2012 were approximately 18% of the total count recorded in December 1995
prior to the series of disturbances to MGRS habitat (CRL 2014).
Prior to the onset of fire exclusion in the mid-1870s (Bahre 1998), MGRS habitat
was likely restricted to the spruce-fir forest and small fire refuge sites. Prior to the 2004
fire, the only known high-severity fire affecting the spruce-fir forest occurred in 1685
5
(Grissino-Mayer et al. 1995, Swetnam et al. 2009, Margolis et al. 2011). The 1685 fire
was stand-replacing over most of the spruce-fir and much of the surrounding mesic
mixed-conifer forest but was low to moderate-severity in fuel-limited dry mixed-conifer
and pine dominated forest (O'Connor 2013). Prior to 1870, median fire return intervals
in mesic mixed-conifer forest surrounding the spruce-fir zone ranged from 17-44 years
and had a strong influence on forest structure and species composition (O'Connor
2013). Fire in mixed-conifer forest sustained open canopy conditions, low stem
densities, and infrequent occurrence of heat-sensitive spruce and corkbark fir.
In this study we reconstruct spatial and temporal dynamics of forest conditions
associated with MGRS habitat over three centuries of fire, spruce beetle outbreaks, and
human land uses. Changes over time to the size and spatial distribution of MGRS
habitat may provide insight into resilience of MGRS populations to habitat loss following
major disturbance events such as the 1996-2004 insect outbreak and fire events.
Placing the current extent of suitable MGRS habitat into a historical context is useful as
a measure of current threats to species survival and for determining management
options best suited to long-term stability of future habitat.
Study area
The spruce-fir and mixed-conifer forests of the Pinaleño Mountains are situated
at the top of ecological and elevational gradients of more than 2,100 meters from 3,267
m in spruce-fir forest down to desert grasslands at 1,150 m (McLaughlin 1993). The
study area is populated primarily by Engelmann spruce (Picea engelmannii Parry ex.
Engelm.) and corkbark fir (Abies lasiocarpa var. arizonica (Hook.) Nutt.) above 2,985 m
6
(9,800 ft), transitioning at lower elevation to mesic mixed-conifer forest with additional
components of Douglas-fir (Pseudotsuga menziesii var. glauca (Mirbel) Franco),
southwestern white pine (Pinus strobiformus Engelmann), and aspen (Populus
tremuloides). The forest surrounding the study area along the central plateau of the
range is primarily dry mixed-conifer forest that also includes white fir (Abies concolor
(Gor. & Glend.) Lindl. ex Hildebr.) and ponderosa pine (Pinus ponderosa var.
scopulorum Engelmann). On steep slopes below 2,135 m (7,000 ft), mixed-conifer
forest transitions abruptly to Madrean pine-oak forest (Quercus spp.) (McLaughlin
1993). Relatively pure stands of ponderosa pine occur infrequently.
A fire burned through most of the spruce-fir forest and parts of the surrounding
mesic mixed-conifer forests with high severity in 1685 (O'Connor 2013). Small patches
of surviving spruce and fir began repopulating the upper elevation forest shortly after the
fire, and much of the spruce-fir zone was under closed canopy conditions by the mid to
late 1700s (O'Connor 2013). No fires entered into the spruce-fir forest for 311 years
until the Clark Peak fire in 1996 burned a small area (91 ha: 10%) of the upper elevation
spruce-fir forest with high severity. Shortly thereafter the 2004 Nuttall Complex fire
burned through 472 ha (52%) of the remaining spruce-fir forest with more than 98%
moderate to high canopy burn severity.
Methods
We reconstructed spatiotemporal dynamics of suitable MGRS habitat by
dendrochronological reconstruction of tree population demographics and fire events
(O'Connor 2013), and evaluation of the reconstructed forest conditions at various times
7
for suitability with respect to forest conditions known to support MGRS (Smith and
Mannan 1994, Merrick et al. 2007).
Forest species demography
To reconstruct forest condition through time, we sampled forest demography
material using a grid of 58 fixed-area 0.05-ha plots spaced 1 km apart over the area
above 2,135 m (7,000 ft). Trees greater than 19.5 cm diameter at breast height (DBH)
were sampled over the full plot area, trees <19.4 cm were sampled in a sub-plot equal
to one third the total plot area (0.017 ha). In the area above 2,835 m (9,300 ft),
containing 75% of known MGRS midden locations, we installed a second fixed-sample
size grid with an additional 21 locations offset 500m from the original sampling grid.
The second grid was used to increase spatial resolution of reconstructed forest
disturbances and changes within the core MGRS habitat. In fixed-sample size plots, the
10 spruce and 10 non-spruce >15 cm DBH nearest to plot center were sampled. In all
plots, up to three increment cores were removed from live trees within 20 cm of mineral
soil. Trees less than 1 cm DBH were cut at the soil surface. Radial cross-sections were
collected from stumps and fallen logs, and quarter round wedges were removed from
snags as close to the root collar as possible.
Increment cores were dried and stored in paper straws prior to mounting and
surfacing. Cut sections were trimmed and mounted to plywood backing if necessary,
and then sanded with progressively finer grits until individual cell structure was
observable (usually 400 grit). Samples were cross-dated using a combination of visual
pattern matching (Yamaguchi 1991), and skeleton plots (Stokes and Smiley 1968). The
8
master chronology developed from Douglas-fir within the spruce-fir zone had the
highest series inter-correlation among all high elevation species and was used to
validate crossdating. On samples that did not include pith, concentric ring pith locators
(Applequist 1958) were used to estimate pith dates if ring curvature indicated pith was
within 10 years of the innermost ring. Ring-width measurements were recorded with J2X
measuring software on a Velmex TA system® with sensor accuracy of one micron
(VoorTech 2010). Crossdating of individual trees was checked with COFECHA
crossdating analysis software (Holmes 1983). Cores that did not correlate with the plotlevel chronology at a level of 0.3 or higher were removed from the analysis (GrissinoMayer 2001).
Demographic reconstruction of seedling recruitment was based solely on fixedarea demography plot data. Recruitment dates from trees with DBH 19.4 cm or smaller
were used in triplicate to account for their collection on only 1/3 of the total plot area.
Recruitment dates were binned by 5-year intervals to account for variability in sampling
heights.
Fire history
To reconstruct fire history we collected fire-scarred material from live trees,
snags, and stumps within the demography plots and while traveling among plots. All
fire-scarred samples collected outside of demography plots were georeferenced and
site characteristics were recorded and photographed. When appropriate, several
samples from individual stumps and snags were collected to preserve as many fire
9
dates as possible (Dieterich and Swetnam 1984). Material was processed in the
laboratory as described previously.
On fire-scarred samples we recorded inner ring or pith date, year and season of
fire, outer year or bark date, and any undetermined scar or growth suppression dates.
Scars of undetermined origin, injury-related growth suppressions, and outer ring dates
corresponding to fire scars recorded within 500 m of a sample were recorded as fire
dates; otherwise they were excluded from fire history analyses.
Spatial reconstruction of 1685 post-fire forest recolonization
The 1685 stand-replacing fire catastrophically reduced suitable MGRS habitat.
We reconstructed the size of the immediate post-1685 spruce- and corkbark firinhabited area and subsequent spatial progression of tree establishment in the burned
area to determine the post-disturbance expansion of potential MGRS habitat. An
interpolated surface of spruce and corkbark fir establishment progression was
generated through inverse distance weighting of earliest establishment dates from the
four nearest plots with a power function of two (ESRI Inc. 2012). Establishment dates
were based on the minimum inner ring date if pith was not present or estimable within
10 years.
Midden density surface
We estimated the historical potential of the forest to support MGRS by evaluating
contemporary forest conditions associated with MGRS midden frequency, and then
quantifying the areas matching those conditions at different points in the past. We used
10
a density of >0.5 middens per hectare to identify sites likely to have been occupied by
MGRS for multiple generations; this value is based on a mean summer core range of 2
hectares per individual and territoriality behavior that reduces overlap of active squirrel
core ranges (Koprowski et al. 2008). Sites with midden density exceeding 0.5 middens
per hectare contain both active and legacy middens, and were used as a proxy for longterm occupancy of the site by MGRS. We used midden locations from the 1996
squirrel midden survey to generate a midden density surface for conditions just prior to
recent insect and fire disturbances. The midden density surface was constrained to
include only sites located within 250 m of known middens to reduce potential of overestimating midden density area. Calculated midden densities were classified as low
density (below 0.5 middens/ha), moderate density (0.5-1 midden/ha), and high density
(>1 midden/ha). The midden density surface was then overlaid on the map of historical
fire frequency to examine spatial relationships between long-term site occupancy and
historical fire frequency.
Spatial reconstruction of fire frequency
To create a fire frequency surface covering the upper elevation forest types in
and around MGRS midden locations, we used the 1-km demography sampling grid to
composite all fire records collected within 500 m of a demography plot location
(Dieterich 1980, Farris et al. 2010). Composite records were filtered to include only fires
recorded on two or more trees. A composite record of fire years from multiple samples
over a discrete spatial unit produces a more complete record of fire occurrence because
individual trees and samples are imperfect recorders of fire, and scars are often eroded
or burned off in subsequent events (Dieterich 1980, Dieterich and Swetnam 1984).
11
Compositing of fire records assumes topographic and ecological homogeneity within the
specified scaling unit. While homogeneity at the kilometer scale cannot be assumed for
all forest types and across the vertical gradient sampled in the Pinaleño Mountains,
variability among one km2 gridded cells was assumed to be greater than variability
within cells.
Fire frequency was calculated for each composited plot by dividing the sum of
fire events by the number of years in the analysis period. A fire frequency surface was
then interpolated over the sampled area to identify patterns of fire frequency in relation
to forest types, landscape features, and period of analysis. Interpolation was based on
inverse distance weighting of four nearest point locations with a power function of two
and a raster cell size of 30 m (ESRI Inc. 2012). We used the pre-EuroAmerican
settlement fire frequency surface (1640-1880) to determine MGRS midden location
preference as a function of mean fire return interval (MFI).
Results
A dominant pattern in the forest demography and fire datasets is the major
increase in successful seedling recruitment and associated increased stem densities in
the mixed-conifer forest following the fire exclusion in the mid-1880s. Seedling
recruitment per five-year interval rarely surpassed 10 stems per hectare prior to 1900.
After 1900, five-year seedling recruitment increased 600-1000%, averaging more than
50 stems per hectare from 1920 to 1955. Exclusion of fire followed by increased
abundance of shade-tolerant species resulted in improved foraging conditions and food
resources for MGRS throughout much of the high elevation mesic mixed-conifer forest
12
(Figure 1From 1870 to 1996 mean stem densities increased more than 2,300% (range
of 65%-10,500%).
Figure 1 Seedling recruitment in mixed-conifer forest 1685 – 2008.
Increase in seedling recruitment after 1880 coincides with EuroAmerican
settlement and the interruption of pre-settlement fire regimes (N= 11, 0.05 ha
plots). Increased stem densities following fire exclusion may provide improved
MGRS habitat quality in the mesic mixed-conifer forest. Low seedling
recruitment after 1970 suggests that the mixed-conifer forest was fully stocked
after this time.
In contrast to the abrupt increase in seedling recruitment and stand densities
observed in the mixed-conifer forest following fire exclusion, seedling recruitment and
species in the higher elevation spruce-fir forest were not affected by fire exclusion. No
13
fires occurred in the spruce-fir forest between 1685 and 1996, so the effects of
anthropogenically-driven fire exclusion were restricted to vegetation communities
located below the spruce-fir along the elevational gradient. Seedling recruitment in the
spruce-fir zone in the first 150 years following the 1685 stand replacing fire was
dominated by Engelmann spruce and corkbark fir with minor components of Douglas-fir
and southwestern white pine. Over the whole of the reconstructed period, seedling
recruitment averaged 15 stems per five-year interval, with a range of 0-50. After 1860,
shade-tolerant spruce and corkbark fir were the primary species recruiting, though
occasionally aspen continued to recruit in individual sites until 1920. Similar to the
record from mixed-conifer plots, no recruitment of any species was recorded in sprucefir plots from 1975 to 2004, suggesting that resources for understory recruitment were
saturated in high-elevation sites prior to the 2004 fire.
14
Figure 2 Seedling recruitment in spruce-fir forest from 1685 through 2008.
Seedling recruitment demonstrates periodic pulses related to disturbance from
spruce beetle outbreaks (N = 6, 0.05-ha plots). In contrast to the mixed-conifer
forest, recruitment does not appear to be affected by EuroAmerican settlement
in the 1880s. A trend of increasing domination of recruitment by corkbark fir and
Engelmann spruce can be seen by the mid-1800s. Low seedling recruitment
after 1950 suggests that the spruce-fir forest was fully stocked prior to the series
of insect outbreaks and fires of the 1990s.
Spruce and corkbark fir recovery following 1685
For the first fifty years following the high-severity fire in 1685, spruce seedling
establishment was limited to four small refuge populations totaling fewer than 200 ha
(Figure 3, Table 1). By 1870, the area occupied by Engelmann spruce exceeded 900
ha, representing the maximum extent of the spruce-containing forest prior to the onset
15
of fire exclusion at lower elevations. Over the next 33 years, Engelmann spruce and
corkbark fir aggressively colonized mixed-conifer areas where fires were excluded,
nearly doubling their occupied area (Figure 3 & 4). Spruce and corkbark fir extent
continued to increase throughout the 20th century fire-free interval, eventually reaching a
maximum extent of more than 2, 200 ha by the mid-1970s.
Figure 3 Temporal progression of Engelmann spruce establishment
following the stand replacing fire in 1685. The map extent is limited to the
forested area above 2,835 m elevation. The age surface is interpolated from
44 gridded point locations. The interpolation is based on an inverse distance
weighting algorithm that uses four nearest point locations with a power
function of two (O’Connor 2013).
16
The maximum spatial extent of corkbark fir (705 ha) and Engelmann spruce (913
ha) in 1870 probably reflects the approximate size of the cool, moist forest type
unaffected by fires in surrounding forest types in the 200 years between the 1685 stand
replacing fire and exclusion of fire in the mixed-conifer in the mid-1880s.
Figure 4. Temporal progression of corkbark fir establishment
following the stand replacing fire in 1685. The map extent is limited to
the forested area above 2,835 m elevation. The age surface is interpolated
from 37 gridded point locations. Spatial interpolation is based on an
inverse distance weighting algorithm that uses four nearest point locations
with a power function of two (O’Connor 2013).
17
Table 1. New and cumulative area occupied by corkbark fir and
Engelmann spruce after a high-severity fire in 1685, at 40-year
intervals and in 2008. The area occupied by corkbark fir (ABLA) and
spruce (PIEN) is a proxy for MGRS habitat in the area where fire was
naturally excluded.
ABLA
PIEN
Year
New ha Cumulative ha
New ha
Cumulative ha
1755
71
71
190
190
1796
123
194
233
423
1835
242
436
238
661
1870
269
705
252
913
1903
686
1,391
731
1,643
1933
457
1,848
498
2,141
1976
249
2,096
196
2,337
2008
-1,308
788
-1,308
1,029
Midden density surface in relation to fire and forest recolonization
Locations of 1,033 middens recorded in the 1996 midden census (CRL 2014)
were used to develop a midden density surface for the 2,718 ha used by MGRS at that
time. The squirrel population from 1989 to 2013 peaked from 1995 to 1996 (CRL 2014).
The area where midden density exceeded 0.5 middens per hectare (949 ha) is
approximately one third of the total area occupied by MGRS in 1996 (Figure 5, Table 1).
18
Figure 5. Midden density during 1996 with respect to historical
(pre- fire exclusion) fire frequency. The fire frequency surface is
based on inverse distance weighting of 53 composited 1-km2 sites
using four nearest neighbors and a power factor of two. Fire frequency
is calculated from 104 spatially reconstructed fire events recorded in
two or more sites from 1640-1880 (O’Connor 2013).
Areas where midden density exceeded 0.5/ha tended to be located where
historical mean fire return interval (MFI) was greater than 33 years (89% of sites), and
usually (64% of sites) where MFI exceeded 100 years (Table 2). In the 204 ha area
where midden density exceeded 1 midden/ha, 77% of sites had historical fire return
intervals greater than 100 years, and 92% had historical fire return intervals greater than
33 years.
19
Table 2. Mount Graham red squirrel midden density in relation
to historical mean fire return interval (MFI). Percentage values
are the proportion of low, moderate, and high midden density
sites located in areas with prolonged fire-free periods prior to
EuroAmerican settlement (1640-1880) (Figure 5).
MFI (years)
Midden Density
Low
Moderate
High
Mod+High
middens/Ha
< 0.5
0.5 - 1
>1
> 0.5
< 33
> 33
> 100
% of sites
% of sites % of sites
53
47
28
12
88
60
8
92
77
11
89
64
The 1996 midden survey identified low-densities of MGRS middens throughout
the mixed-conifer forest (supplemental figures S-1 and S-2), although high midden
densities were consistently associated with the long-term presence of spruce and
corkbark fir (Table 3A). During the EuroAmerican settlement period, when extent of
spruce and corkbark fir doubled in approximately 30 years (from 1870-1903), sites with
high midden density were most strongly associated with the spatial distribution of
corkbark fir (Table 3B). Prior to EuroAmerican settlement and fire interruption, sites
with high midden density were more strongly associated with the distribution of
Engelmann spruce (Table 3C).
20
Table 3 Mount Graham red squirrel midden density in relation to historical extent of
Engelmann spruce and corkbark fir. Percentage values in 1976 (yellow) are the
proportion of total midden area occurring within forest containing spruce (PIEN) and
corkbark fir (ABLA). Percentage values in 1903 (green) and 1870 (blue) represent the
proportion of midden density classes found in sites occupied by corkbark fir and spruce
in early fire exclusion and pre-fire exclusion periods respectively.
A.
Midden
Density
Low
Moderate
High
Mod+High
Middens/ha
< 0.5
0.5 - 1
>1
> 0.5
ABLA
42
66
95
72
Proportion of midden area (%)
1976
B. Pre 1903
C. Pre 1870
PIEN
47
66
93
72
ABLA
56
91
83
89
PIEN
72
62
69
64
ABLA
24
37
64
44
PIEN
29
47
64
52
The majority of the area with midden density exceeding 0.5 middens/ha, an
estimate of pre-fire exclusion MGRS habitat, experienced moderate to high fire severity
in 1685 (Figure 6A). Small patches of mature spruce, corkbark fir, Douglas-fir, and
southwestern white pine, important seed sources for MGRS (Froehlich 1990), are
known to have survived within the high-severity extent of the 1685 fire (O’Connor 2013).
The post-1685 MGRS population would likely have been dependent upon these small
patches for several decades following the fire.
Recent fires negatively affected MGRS habitat, but to a lesser degree than the
1685 fire because active fire suppression efforts prevented the entire spruce-fir
community from burning. The recent fires had a greater proportion of mixed- and highseverity burn patches than the 1685 fire (O’Connor 2013) but more than 1,000 ha of
spruce and fir-containing forest were not burned (Figure 6B). Several areas of highest
midden density remain unburned by recent fires, although many of these sites are
located within the core spruce-fir zone that experienced significant insect-caused
mortality, which degraded MGRS habitat quality (Koprowski et al. 2005).
21
Figure 6. Mount Graham red squirrel core habitat in relation the 1685 fire
and recent stand-replacing fires. The 1685 fire severity is reconstructed from
fire scars and post-fire seedling recruitment from 53 point locations (Part A.). The
fire severity surface is interpolated with inverse distance weighting of four nearest
neighbors with a power function of two. Recent fire severity classes are
generated from reclassified relative difference normalized burn ratio (rdNBR) from
the MTBS database (MTBS 2013) using the method of Miller and Thode (2007)
(Part B.). Fire spatial extents are clipped to the study area.
22
Discussion
The size and quality of habitat suitable for use by MGRS has changed
significantly over the past several centuries. At the start of squirrel monitoring efforts in
1989, more high-quality habitat was available than at any time in the 300-year historical
reconstruction. Suitable habitat peaked in 1995 as the result of more than a century of
fire exclusion from mixed-conifer forests surrounding the spruce-fir zone. High midden
density within the spruce-fir forest zone suggests that multiple generations of MGRS
used these sites prior to expanding into mixed-conifer forest in response to fire
exclusion. Exclusion of fire from mixed-conifer forests led to an infilling of forest
understory with shade tolerant species and eventual canopy closure that would have
limited predation by aerial predators and increased stand density. In addition, the
elimination of spreading fires increased the residence time of fallen logs and other
substrates for fungal reproduction, further enhancing food resources for MGRS (Young
et al. 1997). The century of structural and species changes in mixed-conifer forest
facilitated dispersal of MGRS midden sites throughout the mixed-conifer forest where
some midden locations occurred along the edge of the mixed-conifer-Madrean pine-oak
ecotone on sites that experienced frequent fire prior to EuroAmerican settlement. Even
with the significant expansion of available habitat, high midden densities suggest that
the spruce-fir forest remained the preferred habitat for MGRS into the mid-1990s.
The series of insect outbreaks and fires in the spruce-fir zone that began in 1996
significantly altered habitat quality of MGRS by reducing food resources and shelter
from predators (Koprowski et al. 2005, Koprowski et al. 2006). Current MGRS habitat
quality and extent within the spruce-fir zone has been reduced to approximately 1,030
23
ha, a decline of 56% from 1996 levels. Mixed-conifer forest surrounding the spruce-fir
zone was largely unaffected by the 1990s insect outbreaks and large areas were
untouched by the 1996 and 2004 fires, though spruce aphid and mountain pine beetle
have had some effects in this forest (Lynch 2009, Lynch and O'Connor 2013). Much of
the current mixed-conifer forest has not experienced fire for more than a century
(O’Connor 2013), suggesting that optimum habitat for MGRS may have shifted to
mixed-conifer forest for at least the next several decades depending upon the ability of
the spruce-fir forest to recover under warmer and drier conditions than the post-1685
period.
Suitable habitat for MGRS has been through significant reductions in the past,
most notably following the high-severity fire in 1685. Fewer than 200 ha of suitable
spruce-fir and mesic mixed-conifer forest appear to have survived the 1685 fire. The
fire would have extremely reduced available food resources, structural components that
provide nest and midden locations, and escape cover from predators, probably resulting
in a considerable reduction in the MGRS population. High levels of charcoal deposition
in a cienega near the center of the spruce-fir forest type corresponding to the 1685 fire
(Anderson and Smith 2009) occurred only two other times in the past 5,000 years,
suggesting that large, high-severity fires in the spruce-fir forest are relatively rare
events. The degree of MGRS habitat destruction attributable to the 1685 fire, the rarity
of such destructive events, and the relatively short evolutionary time since the 1685 fire
suggest that conditions in 1685 and the decades afterward may be responsible for the
high levels of inbreeding found in the current MGRS population (Fitak et al. 2013).
24
Ability of MGRS populations to persist in the fire-adapted mixed-conifer forest is
not well understood. The current distribution of middens does not support the
suggestion that MGRS may be adapted to patchy, low severity fires (Leonard and
Koprowski 2010). The majority of sites with high midden densities occurred where
mean fire return intervals exceeded 100 years. Most of the middens located on sites
that were subject to frequent, patchy, low-severity fires in the past are on the outer
edges of current MGRS habitat, and have not experienced fire for more than a century.
The abundance of middens located in low fire-frequency sites suggests that squirrels
preferentially select sites that rarely experience fire.
MGRS habitat and other forest disturbances
In a reconstruction of historical spruce beetle outbreaks in the spruce-containing
forests of the Pinaleño Mountains following 1685, O’Connor (2013) found that outbreaks
occurred approximately every 20 years from 1780-1996 but that the 1996-2002
outbreak was the most severe in the record. Prior outbreaks may have selectively
reduced the number of mature Engelmann spruce by 10-20%, causing a temporary shift
in available MGRS food sources toward seeds of other species. The severity of the
most recent spruce beetle outbreak was likely a function of 1) the largest contiguous
spruce extent in at least 300 years, 2) old growth spruce-fir forest structure with high
basal area, 3) accelerated insect development catalyzed by the highest mean summer
and spring temperatures in a century, and 4) tree stress resulting from prolonged spring
drought conditions (O’Connor 2013).
25
Future habitat outlook
The mixed-conifer forest that now supports the majority of the MGRS population
is still threatened by the prospect of another large, high-severity fire as Arizona
continues to experience record low winter precipitation and above average
temperatures (CLIMAS 2014). Addressing this concern, the Pinaleño Ecosystem
Restoration Project (USDA Forest Service 2010) aims to reduce fuel loading through
thinning and fuel removal in the dry mixed-conifer and parts of the mesic mixed-conifer
forest area. The project restoration plan does not allow thinning treatments in core
MGRS habitat in the mesic mixed-conifer zone, relying instead on fuels reductions in
pine and dry mixed-conifer forest to limit fire spread into remaining MGRS habitat.
Treatments will probably reduce the threat of canopy fire spread from adjacent dry
forest systems significantly, but cannot guard against lightning or human-caused fires
initiating in the overly-dense mesic mixed-conifer zone. Thinning operations began the
winter of 2013 and are expected to continue for ten years (Wilcox pers comm.). For the
next several years, crown fire risk will remain high, especially if drought conditions
continue.
The low density and stocking conditions of the unburned insect-damaged sprucefir forest will have low susceptibility to severe bark beetle outbreaks for several, perhaps
many, decades. Small less intense outbreaks may occur in response to projected
favorable climate conditions (Bentz et al. 2010, O'Connor 2013), but available host
resources are now limiting.
26
The future of core MGRS habitat in the spruce-fir forest remains uncertain.
Projected climate envelopes for Southwest species suggest that the area suitable for
Engelmann spruce will diminish significantly over the next century (Rehfeldt 2004,
Notaro et al. 2012). Efforts to plant spruce within the 2004 high-severity burn perimeter
have met with some success, but much of the burned area remains barren. Populations
of MGRS appear to be resilient to severe population declines, and capable of adapting
to multiple food sources. If the former spruce-fir area repopulates with a higher
proportion of Douglas-fir and white fir than in the past, it will still support MGRS. If
upper elevation forests convert to more fire- and drought-adapted vegetation
communities such as Douglas-fir and pine-dominated forest, as is projected under
warmer and dryer conditions, the ability of MGRS to persist may be impaired.
27
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31
Supplemental figures
Figure S-1 Midden density overlaid on Engelmann spruce establishment. The
colored extent is limited to the forested area above 2,835 m elevation. The spruce age
surface is interpolated from 44 gridded point locations. Spatial interpolation is based on
an inverse distance weighting algorithm that uses four nearest point locations with a
power function of two (O’Connor et al. 2013). The midden density surface is generated
from 1033 midden locations in the year 1996.
32
Figure S-2 Midden density overlaid on Corkbark fir establishment. The colored extent is
limited to the forested area above 2,835 m elevation. The corkbark fir age surface is
interpolated from 37 gridded point locations. Spatial interpolation is based on an
inverse distance weighting algorithm that uses four nearest point locations with a power
function of two (O’Connor et al. 2013). The midden density surface is generated from
1033 midden locations in the year 1996.
33