pika |
Because
most people can’t fathom how 0.8 degrees of warming over a century can be
lethal compared to far greater changes on a daily and seasonal basis, advocates
of CO2 warming have littered the media and scientific literature with
apocryphal stories statistically linking cherry-picked data with that small
temperature rise and suggest wide spread future extinctions (i.e. Polar
Bears, Walrus,
Emperor
Penguins, Edith
Checkerspot, Moose,
Golden
Toad ). Pikas are another species that have been repeatedly targeted as an
icon of impending climate doom. Pikas, or boulder bunnies, inhabit talus slopes
(boulder fields) throughout western North America’s mountainous regions. Some
suggest warming has been driving pikas up the mountain slopes, and they will
soon be driven over the edge into the extinction abyss.
The
doomsday stories of the pikas’ “impending extinction” began with a few
contentious papers by Dr. Erik Beever. He re-surveyed a small subset of
Nevada’s pika populations and reported 28%
(7 of 25) of pika territories,
which had been occupied at the beginning of the 20th century, were
now vacant. He suggested those 7 populations had gone extinct possibly due to
climate change. That claim was then trumpeted by groups like the National
Wildlife Federation with articles like “No
Room at the Top.”
As they
had done for polar bears and penguins, the Center of Biological Diversity argued
climate change was threatening species with extinction and sued for pikas to be listed as federally endangered once, and as
California endangered twice. The CBD alarmingly exaggerated Beever’s small
survey to falsely report, “We've already lost almost half of the pikas that
once inhabited the Great Basin.” But to the credit of official wildlife
experts, they rejected those lawsuits due to insufficient evidence. Dismayed
that bad science had been rejected, the CBD called Obama a denier and Joe Romm bemoaned,
“So
long pika, we hardly knew ya.”
Now once
again, dubious science is pushing pikas as another canary in the climate coal
mine. Although the evidence has not supported the pika’s demise, Stewart (2015)
constructed a model that would and published their projections in Revisiting
The Past To Foretell The Future: Summer Temperature And Habitat Area Predict
Pika Extirpations In California. These researchers predict “that
by 2070 pikas will be extirpated from “39% to 88%” of California’s historical
sites.
And once again the media
is hyping that pikas are being pushed up the mountains to their doom.
In
contrast to the hype, Dr. Andrew Smith, the International Union for the
Conservation of Nature pika expert, has testified that pikas are thriving in
California and should not be listed.
Although an avid defender of the Endangered Species Act, he argued that
incorrectly listing the pika as endangered (see
his letter here) would only subject the ESA to greater criticism and
denigrate conservation science.
Due to possible climate change concerns, the US Forest
Service was obligated to extensively survey pika habitat throughout the national
forests of the Sierra Nevada and the Great Basin. Supporting Dr. Smith’s views,
in 2010 they too reported
thriving pikas. Overall, only 6% of observed pika territories were vacant. Due
to the lack of connectivity with other pika territories, when a pika dies the
smaller more isolated territories suffer longer periods of vacancy.
Accordingly, the USFS reported that vacancy rates increased as surveys moved
from the Sierra Nevada with its large interconnected talus slopes to more
isolated habitat in the Great Basin. In the Sierra Nevada the vacancy rate was
just 2%, in the southwestern Great Basin vacancies increased to 17%, and vacancies
were highest, 50%, in more isolated habitat of the central Great Basin ranges. The
larger percentage of unoccupied sites east of the Sierra Nevada crest was typically
due to the greater difficulty of finding and re‑colonizing relatively small and
isolated habitat.
USFS surveys provided more damning evidence that would
lead to rejecting the CBD’s lawsuits. The benchmark for wildlife abundance and
distribution in California had been Joseph Grinnell’s surveys from the early
1900s. Contrary to global warming theory, the USFS survey found many new active
pika colonies several hundred meters
lower than Grinnell had documented. In total, 19% of the currently known populations are at lower elevations than
ever documented by any study during the cooler 1900s. Further north in the
Columbia River Gorge, another independent
researcher also found pikas at much lower elevations, surviving at
temperatures much higher than the models had predicted.
Beever’s
2011 paper tried to counter those findings by arguing there was a nearly “five-fold increase in the rate of local
extinctions and an 11-fold increase in the rate of upslope range retraction
during the last ten years.” But Beever had badly manipulated his data. Surveying
his 25 sites, he too had found 10 examples where pikas now inhabited lower
elevations than previously documented. But he
decided not to use those observations in his calculations. He, the editors
and peer-reviewers unapologetically published his biased calculations to create
his “11-fold increase in the rate of
upslope range retraction”. Beever defended this statistical blasphemy by
arguing pikas had likely always lived at those lower elevations, but had
escaped detection by earlier observers (the equivalent of climate science
infilling). Perhaps. It was possible. But by eliminating all new observations
of pikas at warmer, lower elevations, he guaranteed
their statistical upslope retreat.
Here’s
an example of his calculations:
At Cougar Peak, a 1925 record documented the lowest elevation that pikas
had inhabited was 2416 meters.
Beever’s more recent surveys detected pikas living even lower on Cougar Peak at
2073 meters in the late 1990s, and at 2222 metes in follow‑up surveys in 2003. Despite the fact that recent
observations were all lower than 1925 by about 200 meters, Beever ignored the
historical record. He simply subtracted the 1990s elevation from the 2003
elevation, to report climate had pushed pikas 149 meters higher. Furthermore,
the Cougar Peak site was one of the sites Beever had initially reported as
extinct. Follow-up surveys found a
robust population.
Vacant pika territories are natural and to be expected.
Pika are very territorial and each year they drive their young away. Because
pika live no longer than 7 years, (averaging 3 to 4 years in the wild), there
is constant turnover at each site. A site remains vacant until a young pika,
driven from another territory, randomly scampers into that vacancy and claims
ownership. Without knowing how often a talus pile alternates between occupied
and vacant, simply reporting observations of a vacant site tells us nothing
about 1) why it is vacant, 2)
when it was vacated, and 3) if it will soon be recolonized. Unfortunately
vacancies have been misleadingly called extinctions. To illustrate, in the most
recent paper by Stewart, his team initially found 15 vacancies, but a re‑survey
the following year, found that 5 of those sites were now re‑colonized, a 33%
reduction in “extinct locations” in just one year.
Re‑colonization has similarly undermined other classic
doomsday stories. Parmesan’s iconic 1996 paper reported global warming had
increased extinctions for the Edith’s Checkerspot butterfly, but most of those
extinct colonies in the Sierra Nevada have now been re‑colonized. Unfortunately
the re‑colonization information was never published. (read here
and here).
The IUCN’s Dr. Andrew Smith is the only researcher with
results from long term pika monitoring that actually provides insight into the
natural frequency of “extinction” and re‑colonization.
Pika on Bodie ore piles |
In California’s abandoned desert mining town of Bodie,
pika have colonized discarded ore piles. Dr. Smith tracked the vacancy rates of
76 ore piles from 1972 to 2009. As expected, during those 37 years Smith
observed 107
local extinctions, balanced by 106 re-colonizations. Like pika habitat
elsewhere in the Great Basin, on average 30% of the ore piles were unoccupied
at any given time, but that vacancy rate was highly variable. Some years the
vacancy rate was as high as 52%, and other years as low as 11% (see chart
below). In his first survey in 1972, Smith found that 82.3% of the ore piles
were occupied by pika. In 2009, pika again occupied 82.8% of their possible
sites. Coincidentally Stewart (2015) found 85% (57/67) of his re-surveyed sites
are now occupied. Without accounting for such a wide range of variability, the
percentage of vacant territories tells us precious little about any climate
effects. But in contrast to Smith’s analysis, Stewart presented vacant
territories as evidence of global warming caused “extinctions”.
Pika Colonizaton and Extinctions at Bodie |
Although Smith’s research establishes a natural frequency
of vacancy rates, it still doesn’t tell us why a site became vacant. In
Beever’s 2003 paper, the seven “extinct” sites he attributed to climate change
had other more plausible explanations. One site had half of the talus removed
for road maintenance, another site had become a dump site, and a third site had
scattered shotgun shells throughout the talus.
Like rabbits, and a truly endangered species of pika in
China, pikas have been hunted and poisoned because they compete with livestock
for vegetation. All of Beever’s extinct
sites were heavily grazed. Furthermore pikas do not hibernate. They
create hay piles to sustain them through the winter. Any significant loss of
vegetation will likely cause pikas to abandon their talus. Although studies
have reported significant effects from grazing competition, Stewart (2015) did
not include grazing as a variable in his climate change model.
Stewart (2015) created a model that only included 1) area of talus and 2) summer mean temperature as the
determinants of local pika extinctions. Assuming that model represents reality,
they then argued that according to projected warming from CO2 driven models,
pika will become increasingly “extirpated from 39% to 88% of these historical sites”.
But talus area is the more critical variable, and the
average summer temperature is highly questionable. Larger talus areas sustain
more pika territories, and provide protection for dispersing young looking for
vacancies. With more adjacent territories, there are more young pika who can
immediately occupy any abandoned territory. In contrast the smallest talus
areas, often sustaining just a single territory, are islands that lack
connectivity to other territories. Vacant territories must wait to be randomly
colonized by dispersing young from some distance talus. As the distance between
isolated territories increases it is less likely that randomly dispersing young
will re‑colonize a vacated territory. But the degree of connectivity was also
never considered in Stewart’s model. As seen in his diagram below (I added the
red lines for reference), the vacancies can be readily explained just by the
talus area and random dispersal.
Stewart 2015 pika model |
If the size of the talus area had been modeled as the only predictor of pika vacancies, any
large talus area, (areas above the upper red line), would correctly predict
full occupancy, accounting for 31% of the sites (20 of 67), regardless of
temperature. Small talus area (areas below the lower red line) would correctly
account for 70% of the vacancies (7 of 10 vacancies) regardless of temperature.
In talus of intermediate areas, only 7% of the sites were vacant (3 of 39)
which is close to the overall 6% finding of the USFS surveys. That 7% vacancy
rate is easily accounted for by random extinction/colonization events, and the
percentage is far better than vacancy rates Dr. Smith reported for Bodie’s ore
piles.
The higher temperatures reported at the 3 vacancies with
intermediate talus areas may have been the result of a more barren dry
landscape typical of the eastside of the Sierra Nevada. If so, lack of food,
not higher temperatures may be the critical factor. Stewart never asks if the
vacancies are due to higher temperatures, less reliable vegetation, or distance
from other territories. Stewart’s model statistically linked higher temperatures
to pika vacancies, but that link depends on what sites he includes or omits in
his database.
Beever’s data had similarly suggested higher temperatures
were killing pika, but his analysis excluded data from nearby populations thriving
at warmer and lower elevations just 93 miles away from 71% of Beever’s extinct
sites. At Lava Beds pika were flourishing at an average elevation 900 feet
lower than the average elevation of three nearby extinct sites. Temperatures at
Lava Beds also averaged an additional 3.6°F higher, and precipitation was 24%
less. But Beever analyzed
those sites separately. Likewise Stewart was clearly more interested in a
connection to global warming. In his introduction he speculated, “climate
change forces range contractions, species
may effectively be ‘pushed off’ the tops of mountains by warming climate.”
He also referenced Parmesan’s
bad climate science connection for support. To create a link to global
warming, Stewart needed to use average
summer temperature as the other model variable.
During high temperatures, heat-sensitive pika will seek
refuge beneath the cooler talus. However Stewart argues such behavior reduces
critical foraging time and thus possibly reduces winter survival. Perhaps.
During extreme warm days, pika are known to become crepuscular, restricting
their foraging to the twilight hours. However if that is the key mechanism, then
using the average temperature is simply wrong. The average temperature is
amplified by minimum temperatures of the early morning when overheating is not
a problem. If Stewart was sincerely concerned about induced heat stress, then
the correct metric would be the afternoon maximum temperatures. But maximums
were not even considered in Stewart’s choice of models.
Not considering maximum temperatures would seem shamefully
negligent, but Stewart was aware that other studies had already determined no
correlation with maximum temperatures. Stewart referenced Beever (2010)
who wrote, ““Although pikas have been shown to perish quickly when
experimentally subjected to high temperatures, our metric of acute heat stress was the poorest predictor
of pika extirpations.” Because maximum temperatures had revealed no acute
heat stress, Beever adopted the term “chronic heat stress” which was just a
more alarming way to say the average temperature. But even using average temperature, Beever still concluded, “Climate change metrics were by far the poorest
predictor of pika extirpation.” Stewart’s own data supported
the conclusion that climate metrics provided poor explanatory power.
Stewart also cherry-picked a start date to argue,
“documented 1°C increases in California-wide summer temperature over the past
century, strongly suggest that pikas have experienced climate-mediated range
contraction in California over the past century.” However if one examines the
data Stewart links to for northeastern California, where most of their
“extinctions” were observed, recent summer maximum temperatures have not
exceeded the 1920s and 30s. If pika extinctions were truly “climate-mediated”,
then the high temperatures of the 20s and 30s should have been the main driver.
Furthermore during that 20s and 30s, pika experienced the most rapid
temperature increases of about 2°C (4°F) in just 3 decades.
Northeast California Maximum Temperatures |
Stewart made one more feeble attempt to justify using
average summer temperatures. He reported that a 2005 paper by Grayson
revealed pika have been forced to move ever upwards as climate warmed
throughout the Holocene. (See graph below) But Stewart seems unaware that he
damaged is own argument. Several
studies, using proxies and models, have shown the Great Basin was warmer
during the Middle Holocene by 1 to 2.5°C. Using Stewart’s logic, as global
warming approaches temperatures seen in the mid Holocene, pika should descend
to lower elevations.
Although summer temperature data has very little
predictive power regards pika biology, it was Stewart’s only link to CO2
climate models. Using that dubious link to summer temperatures, he projects
impending climate doom and widespread pika extinctions. But if Stewart was
truly concerned about preserving pikas, instead of preserving CO2 theory, then
all the data suggests small talus areas that are subjected to grazing are the
relevant concern. To protect the pikas’ forage, simply fencing off livestock
from the edge of those small talus slopes would be a simple affordable
solution. Stewart’s own data also suggests, along with the USFS surveys, that wherever there is large talus
area, there has been nothing to suggest imminent extinctions. So why does the
pikas’ climate change extinction story persist?
Grayson's depiction of elevations of pika habitat in the Holocene |