FIELD NOTES FROM A CATASTROPHE
MAN, NATURE, AND CLIMATE CHANGE
By Elizabeth Kolbert
BLOOMSBURY
Copyright © 2006
Elizabeth Kolbert
All right reserved.
ISBN: 1-59691-125-5
Contents
Preface...................................................1
Part I: Nature............................................5
Chapter 1: Shishmaref, Alaska.............................7
Chapter 2: A Warmer Sky...................................35
Chapter 3: Under the Glacier..............................45
Chapter 4: The Butterfly and the Toad.....................67
Part II: Man..............................................89
Chapter 5: The Curse of Akkad.............................91
Chapter 6: Floating Houses................................120
Chapter 7: Business as Usual..............................131
Chapter 8: The Day After Kyoto............................148
Chapter 9: Burlington, Vermont............................171
Chapter 10: Man in the Anthropocene.......................181
Chronology................................................189
Acknowledgments...........................................193
Selected Bibliography and Notes...........................195
Index.....................................................205
Chapter One
SHISHMAREF, ALASKA
THE ALASKAN VILLAGE of Shishmaref sits on an
island known as Sarichef, five miles off the coast of the
Seward Peninsula. Sarichef is a small island-no more than
a quarter of a mile across and two and a half miles long-and
Shishmaref is basically the only thing on it. To the
north is the Chukchi Sea, and in every other direction lies
the Bering Land Bridge National Preserve, which probably
ranks as one of the least visited national parks in the
country. During the last ice age, the land bridge-exposed
by a drop in sea levels of more than three hundred feet-grew
to be nearly a thousand miles wide. The preserve
occupies that part of it which, after more than ten thousand
years of warmth, still remains above water.
Shishmaref (population 591) is an Inupiat village, and it
has been inhabited, at least on a seasonal basis, for several
centuries. As in many native villages in Alaska, life there
combines-often disconcertingly-the very ancient and
the totally modern. Almost everyone in Shishmaref still
lives off subsistence hunting, primarily for bearded seals but
also for walrus, moose, rabbits, and migrating birds. When
I visited the village one day in April, the spring thaw was
under way, and the seal-hunting season was about to
begin. (Wandering around, I almost tripped over the
remnants of the previous year's catch emerging from
storage under the snow.) At noon, the village's transportation
planner, Tony Weyiouanna, invited me to his house
for lunch. In the living room, an enormous television set
tuned to the local public-access station was playing a rock
soundtrack. Messages like "Happy Birthday to the following
elders ..." kept scrolling across the screen.
Traditionally, the men in Shishmaref hunted for seals by
driving out over the sea ice with dogsleds or, more
recently, on snowmobiles. After they hauled the seals back
to the village, the women would skin and cure them, a
process that takes several weeks. In the early 1990s, the
hunters began to notice that the sea ice was changing.
(Although the claim that the Eskimos have hundreds of
words for snow is an exaggeration, the Inupiat make
distinctions among many different types of ice, including
sikuliag, "young ice,"
sarri, "pack ice," and
tuvag,
"land-locked ice.") The ice was starting to form later in the fall,
and also to break up earlier in the spring. Once, it had been
possible to drive out twenty miles; now, by the time the
seals arrived, the ice was mushy half that distance from
shore. Weyiouanna described it as having the consistency
of a "slush puppy." When you encounter it, he said, "your
hair starts sticking up. Your eyes are wide open. You can't
even blink." It became too dangerous to hunt using
snowmobiles, and the men switched to boats.
Soon, the changes in the sea ice brought other problems.
At its highest point, Shishmaref is only twenty-two feet
above sea level, and the houses, most of which were built
by the U.S. government, are small, boxy, and not particularly
sturdy-looking. When the Chukchi Sea froze early,
the layer of ice protected the village, the way a tarp
prevents a swimming pool from getting roiled by the
wind. When the sea started to freeze later, Shishmaref
became more vulnerable to storm surges. A storm in
October 1997 scoured away a hundred-and-twenty-five-foot-wide
strip from the town's northern edge; several
houses were destroyed, and more than a dozen had to be
relocated. During another storm, in October 2001, the
village was threatened by twelve-foot waves. In the summer
of 2002, residents of Shishmaref voted, a hundred and
sixty-one to twenty, to move the entire village to the
mainland. In 2004, the U.S. Army Corps of Engineers
completed a survey of possible sites. Most of the spots that
are being considered for a new village are in areas nearly as
remote as Sarichef, with no roads or nearby cities or even
settlements. It is estimated that a full relocation would cost
the U.S. government $180 million.
People I spoke to in Shishmaref expressed divided
emotions about the proposed move. Some worried that,
by leaving the tiny island, they would give up their
connection to the sea and become lost. "It makes me feel
lonely," one woman said. Others seemed excited by the
prospect of gaining certain conveniences, like running
water, that Shishmaref lacks. Everyone seemed to agree,
though, that the village's situation, already dire, was only
going to get worse.
Morris Kiyutelluk, who is sixty-five, has lived in Shishmaref
almost all his life. (His last name, he told me, means
"without a wooden spoon.") I spoke to him while I was
hanging around the basement of the village church, which
also serves as the unofficial headquarters for a group called
the Shishmaref Erosion and Relocation Coalition. "The
first time I heard about global warming, I thought, I don't
believe those Japanese," Kiyutelluk told me. "Well, they
had some good scientists, and it's become true."
The National Academy of Sciences undertook its first
major study of global warming in 1979. At that point,
climate modeling was still in its infancy, and only a few
groups, one led by Syukuro Manabe at the National
Oceanic and Atmospheric Administration and another
by James Hansen at NASA's Goddard Institute for Space
Studies, had considered in any detail the effects of adding
carbon dioxide to the atmosphere. Still, the results of their
work were alarming enough that President Jimmy Carter
called on the academy to investigate. A nine-member
panel was appointed. It was led by the distinguished
meteorologist Jule Charney, of MIT, who, in the 1940s,
had been the first meteorologist to demonstrate that
numerical weather forecasting was feasible.
The Ad Hoc Study Group on Carbon Dioxide and
Climate, or the Charney panel, as it became known, met
for five days at the National Academy of Sciences' summer
study center, in Woods Hole, Massachusetts. Its conclusions
were unequivocal. Panel members had looked for
flaws in the modelers' work but had been unable to find
any. "If carbon dioxide continues to increase, the study
group finds no reason to doubt that climate changes will
result and no reason to believe that these changes will be
negligible," the scientists wrote. For a doubling of C[O.sub.2]
from preindustrial levels, they put the likely global temperature
rise at between two and a half and eight degrees
Fahrenheit. The panel members weren't sure how long it
would take for changes already set in motion to become
manifest, mainly because the climate system has a built-in
time delay. The effect of adding C[O.sub.2] to the atmosphere is
to throw the earth out of "energy balance." In order for
balance to be restored-as, according to the laws of
physics, it eventually must be-the entire planet has to
heat up, including the oceans, a process, the Charney panel
noted, that could take "several decades." Thus, what
might seem like the most conservative approach-waiting
for evidence of warming to make sure the models were
accurate-actually amounted to the riskiest possible strategy:
"We may not be given a warning until the C[O.sub.2]
loading is such that an appreciable climate change is
inevitable."
It is now more than twenty-five years since the
Charney panel issued its report, and, in that period,
Americans have been alerted to the dangers of global
warming so many times that reproducing even a small
fraction of these warnings would fill several volumes;
indeed, entire books have been written just on the
history of efforts to draw attention to the problem. (Since
the Charney report, the National Academy of Sciences
alone has produced nearly two hundred more studies on
the subject, including, to name just a few, "Radiative
Forcing of Climate Change," "Understanding Climate
Change Feedbacks," and "Policy Implications of Greenhouse
Warming.") During this same period, worldwide
carbon-dioxide emissions have continued to increase,
from five billion to seven billion metric tons a year,
and the earth's temperature, much as predicted by Manabe's
and Hansen's models, has steadily risen. The year
1990 was the warmest year on record until 1991, which
was equally hot. Almost every subsequent year has been
warmer still. As of this writing, 1998 ranks as the hottest
year since the instrumental temperature record began, but
it is closely followed by 2002 and 2003, which are tied for
second; 2001, which is third; and 2004, which is fourth.
Since climate is innately changeable, it's difficult to say
when, exactly, in this sequence natural variation could be
ruled out as the sole cause. The American Geophysical
Union, one of the nation's largest and most respected
scientific organizations, decided in 2003 that the matter
had been settled. At the group's annual meeting that year,
it issued a consensus statement declaring, "Natural influences
cannot explain the rapid increase in global near-surface
temperatures." As best as can be determined, the
world is now warmer than it has been at any point in
the last two millennia, and, if current trends continue, by
the end of the century it will likely be hotter than at any
point in the last two million years.
In the same way that global warming has gradually
ceased to be merely a theory, so, too, its impacts are no
longer just hypothetical. Nearly every major glacier in the
world is shrinking; those in Glacier National Park are
retreating so quickly it has been estimated that they will
vanish entirely by 2030. The oceans are becoming not just
warmer but more acidic; the difference between daytime
and nighttime temperatures is diminishing; animals are
shifting their ranges poleward; and plants are blooming
days, and in some cases weeks, earlier than they used to.
These are the warning signs that the Charney panel
cautioned against waiting for, and while in many parts
of the globe they are still subtle enough to be overlooked,
in others they can no longer be ignored. As it happens, the
most dramatic changes are occurring in those places, like
Shishmaref, where the fewest people tend to live. This
disproportionate effect of global warming in the far north
was also predicted by early climate models, which forecast,
in column after column of FOR TRAN-generated figures,
what today can be measured and observed directly: the
Arctic is melting.
Most of the land in the Arctic, and nearly a quarter of all
the land in the Northern Hemisphere-some five and a
half billion acres-is underlaid by zones of permafrost. A
few months after I visited Shishmaref, I went back to
Alaska to take a trip through the interior of the state with
Vladimir Romanovsky, a geophysicist and permafrost
expert. I flew into Fairbanks-Romanovsky teaches at
the University of Alaska, which has its main campus
there-and when I arrived, the whole city was enveloped
in a dense haze that looked like fog but smelled like
burning rubber. People kept telling me that I was lucky
I hadn't come a couple of weeks earlier, when it had been
much worse. "Even the dogs were wearing masks," one
woman I met said. I must have smiled. "I am not joking,"
she told me.
Fairbanks, Alaska's second-largest city, is surrounded on
all sides by forest, and virtually every summer lightning sets
off fires in these forests, which fill the air with smoke for a
few days or, in bad years, weeks. In the summer of 2004,
the fires started early, in June, and were still burning two
and a half months later; by the time of my visit, in late
August, a record 6.3 million acres-an area roughly the size
of New Hampshire-had been incinerated. The severity
of the fires was clearly linked to the weather, which had
been exceptionally hot and dry; the average summertime
temperature in Fairbanks was the highest on record, and
the amount of rainfall was the third lowest.
On my second day in Fairbanks, Romanovsky picked
me up at my hotel for an underground tour of the city.
Like most permafrost experts, he is from Russia. (The
Soviets more or less invented the study of permafrost when
they decided to build their gulags in Siberia.) A broad man
with shaggy brown hair and a square jaw, Romanovsky as
a student had had to choose between playing professional
hockey and becoming a geophysicist. He had opted for the
latter, he told me, because "I was little bit better scientist
than hockey player." He went on to earn two master's
degrees and two Ph.D.s. Romanovsky came to get me at
ten A.M.; owing to all the smoke, it looked like dawn.
Any piece of ground that has remained frozen for at least
two years is, by definition, permafrost. In some places, like
eastern Siberia, permafrost runs nearly a mile deep; in
Alaska, it varies from a couple of hundred feet to a couple
of thousand feet deep. Fairbanks, which is just below the
Arctic Circle, is situated in a region of discontinuous
permafrost, meaning that the city is pocked with regions
of frozen ground. One of the first stops on Romanovsky's
tour was a hole that had opened up in a patch of permafrost
not far from his house. It was about six feet wide and five
feet deep. Nearby were the outlines of other, even bigger
holes, which, Romanovsky told me, had been filled with
gravel by the local public-works department. The holes,
known as thermokarsts, had appeared suddenly when the
permafrost gave way, like a rotting floorboard. (The
technical term for thawed permafrost is "talik," from a
Russian word meaning "not frozen.") Across the road,
Romanovsky pointed out a long trench running into the
woods. The trench, he explained, had been formed when a
wedge of underground ice had melted. The spruce trees
that had been growing next to it, or perhaps on top of it,
were now listing at odd angles, as if in a gale. Locally, such
trees are called "drunken." A few of the spruces had fallen
over. "These are very drunk," Romanovsky said.
In Alaska, the ground is riddled with ice wedges that
were created during the last glaciation, when the cold earth
cracked and the cracks filled with water. The wedges,
which can be dozens or even hundreds of feet deep, tended
to form in networks, so when they melt, they leave behind
connecting diamond- or hexagon-shaped depressions. A
few blocks beyond the drunken forest, we came to a house
where the front yard showed clear signs of ice-wedge
melt-off. The owner, trying to make the best of things, had
turned the yard into a miniature-golf course. Around the
corner, Romanovsky pointed out a house-no longer
occupied-that basically had split in two; the main part
was leaning to the right and the garage toward the left. The
house had been built in the sixties or early seventies; it had
survived until almost a decade ago, when the permafrost
under it started to degrade. Romanovsky's mother-in-law
used to own two houses on the same block. He had urged
her to sell them both. He pointed out one, now under new
ownership; its roof had developed an ominous-looking
ripple. (When Romanovsky went to buy his own house,
he looked only in permafrost-free areas.)
"Ten years ago, nobody cared about permafrost," he
told me. "Now everybody wants to know." Measurements
that Romanovsky and his colleagues at the University
of Alaska have made around Fairbanks show that
the temperature of the permafrost in many places has risen
to the point where it is now less than one degree below
freezing. In places where the permafrost has been disturbed,
by roads or houses or lawns, much of it is already
thawing. Romanovsky has also been monitoring the permafrost
on the North Slope and has found that there, too,
are regions where the permafrost is very nearly thirty-two
degrees Fahrenheit. While thermokarsts in the roadbeds
and talik under the basement are the sort of problems that
really only affect the people right near-or above-them,
warming permafrost is significant in ways that go far
beyond local real estate losses. For one thing, permafrost
represents a unique record of long-term temperature
trends. For another, it acts, in effect, as a repository for
greenhouse gases. As the climate warms, there is a good
chance that these gases will be released into the atmosphere,
further contributing to global warming. Although
the age of permafrost is difficult to determine, Romanovsky
estimates that most of it in Alaska probably dates back to
the beginning of the last glacial cycle. This means that if it
thaws, it will be doing so for the first time in more than a
hundred and twenty thousand years. "It's really a very
interesting time," Romanovsky told me.
(Continues...)
Excerpted from FIELD NOTES FROM A CATASTROPHE
by Elizabeth Kolbert
Copyright © 2006 by Elizabeth Kolbert.
Excerpted by permission.
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