In my own work, I
found that the Syrian conflict was
not just triggered by climate change,
but a range of intersecting
factors—Syria’s domestic crude oil
production had peaked in the mid-90s,
leading state revenues to hemorrhage as
oil production and exports declined.
When global climate chaos triggered food
price spikes, the state had begun
slashing domestic fuel and food
subsidies, already reeling from the
impact of economic mismanagement and
corruption resulting in massive debt
levels. And so, a large young population
overwhelmed with unemployment and
emboldened by decades of political
repression took to the streets when they
could not afford basic bread. Syria has
since collapsed into ceaseless civil
war.
This is a case of what
Professor Thomas-Homer Dixon, University
Research Chair in the University of
Waterloo’s Faculty of Environment,
describes as “synchronous failure”—when
multiple, interconnected stressors
amplify over time before triggering
self-reinforcing feedback loops which
result in them all failing at the same
time. In his book, The Upside of Down:
Catastrophe, Creativity and the
Renewal of Civilization, he explains
how the resulting convergence of crises
overwhelms disparate political, economic
and administrative functions, which are
not designed for such complex events.
From this lens,
climate-induced collapse has already
happened, though it is exacerbated by
and amplifies the failure of myriad
human systems. Is Syria a case-study of
what is in store for the world? And is
it inevitable within the next decade?
In a major report
released in August, the UN’s
Intergovernmental Panel on Climate
Change (IPCC)
warned that hunger has already been
rising worldwide due to climate impacts.
A senior NASA scientist, Cynthia
Rosenzweig, was a lead author of the
study, which warned that the continued
rise in carbon emissions would drive a
rise in global average temperatures of
2°C in turn triggering a “very high”
risk to food supplies toward
mid-century. Food shortages would hit
vulnerable, poorer regions, but affluent
nations may also be in the firing line.
As a
new study from the UK Parliamentary
Environment Audit Committee concludes,
fruit and vegetable imports to countries
like Britain might be cut short if a
crisis breaks out.
When exactly such a
crisis might happen is not clear.
Neither reports suggest it would result
in the collapse of civilization, or even
most countries, within 10 years. And the
UN also emphasizes that it is not too
late to avert these risks through a
shift to organic and agro-ecological
methods.
NASA’s Gavin Schmidt
acknowledged “increasing impacts from
climate change on global food
production,” but said that a collapse
“is not predicted and certainly not
inevitable.”
The catastrophic
‘do-nothing’ scenario
A few years ago, though,
I discovered first-hand that a
catastrophic collapse of the global food
system is possible in coming decades if
we don’t change course. At the time I
was a visiting research fellow at Anglia
Ruskin University’s Global
Sustainability Institute, and I had been
invited to a steering committee meeting
for the Institute’s Global Research
Observatory (GRO), a research program
developing new models of global crisis.
One particular model,
the
Dawe Global Security Model, was
focused on the risk of another global
food crisis, similar to what triggered
the Arab Spring.
“We ran the model
forward to the year 2040, along a
business-as-usual trajectory based on
‘do-nothing’ trends—that is, without any
feedback loops that would change the
underlying trend,” said institute
director Aled Jones to the group of
stakeholders in the room, which included
UK government officials. “The results
show that based on plausible climate
trends, and a total failure to change
course, the global food supply system
would face catastrophic losses, and an
unprecedented epidemic of food riots. In
this scenario, global society
essentially collapses as food production
falls permanently short of consumption.”
Jones was at pains to clarify that this
model-run could not be taken as a
forecast, particularly as mitigation
policies are already emerging in
response to concern about such an
outcome: “This scenario is based on
simply running the model forward,” he
said. “The model is a short-term model.
It’s not designed to run this long, as
in the real world trends are always
likely to change, whether for better or
worse.”
Someone asked, “Okay, but what you’re
saying is that if there is no change in
current trends, then this is the
outcome?”
“Yes,” Jones replied quietly.
The Dawe Global Security Model put this
potential crisis two decades from now.
Is it implausible that the scenario
might happen much earlier? And if so why
aren’t we preparing for this risk?
When I asked UN disaster risk advisor
Scott Williams about a near-term global
food crisis scenario, he pointed out
that this year’s UN flagship global
disaster risk assessment was very much
aware of the danger of another global
"multiple breadbasket failure."
“A
projected increase in extreme climate
events and an increasingly
interdependent food supply system pose a
threat to global food security,”
warned
the UN Global Assessment Report on
Disaster Risk Reduction released in May.
“For instance, local shocks can have
far-reaching effects on global
agricultural markets.”
Climate models we've been using are not
too alarmist; they are consistently too
conservative, and we have only recently
understood how bad the situation really
is.
Current agricultural modelling, the UN
report said, does not sufficiently
account for these complex
interconnections. The report warns that
“climate shocks and consequent crop
failure in one of the global cereal
breadbaskets might have knock-on effects
on the global agricultural market. The
turbulences are exacerbated if more than
one of the main crop-producing regions
suffers from losses simultaneously.”
Williams, who was a coordinating lead
author of the UN global disaster risk
assessment, put it more bluntly: “In a
nutshell, Bendell is closer to the mark
than his critics.”
He pointed
me to the
second chapter
of the UN report which, he said,
expressed the imminent risk to global
civilization in a “necessarily
politically desensitized” form. The
chapter is “close to stating that
‘collapse is inevitable’ and that the
methods that we—scientists, modellers,
researchers, etc—are using are wholly
inadequate to understand that nature of
complex, uncertain ‘transitions,’ in
other words, collapses.”
Williams fell short of saying that such
a collapse scenario was definitely
unavoidable, and the UN report—while
setting out an alarming level of
risk—did not do so either. What they did
make clear is that a major global food
crisis could erupt unexpectedly, with
climate change as a key trigger.
Climate
tipping points
A new
study
by a team of scientists at Oxford,
Bristol, and Austria concludes that our
current carbon emissions trajectory
hugely increases this risk. Published in
October in the journal Agricultural
Systems, the study warns that the
rise in global average temperatures is
increasing the likelihood of “production
shocks” affecting an increasingly
interconnected global food system.
Surpassing the 1.5 °C threshold could
potentially trigger major “production
losses” of millions of tonnes of maize,
wheat and soybean.
Right now,
carbon dioxide emissions are on track to
dramatically increase this risk of
multi-breadbasket failures. Last year,
the IPCC found that unless we reduce our
emissions levels by five times their
current amount, we could hit 1.5°C
as early as 2030,
and no later than mid-century. This
would dramatically increase the risk of
simultaneous crop failures, food
production shocks and other devastating
climate impacts.
In April
this year, the European Commission’s
European Strategy and Policy Analysis
System published its second major
report
to EU policymakers, Global Trends to
2030: Challenges and Choices for Europe.
The report, which explores incoming
national security, geopolitical and
socio-economic risks, concluded: “An
increase of 1.5 degrees is the maximum
the planet can tolerate; should
temperatures increase further beyond
2030, we will face even more droughts,
floods, extreme heat and poverty for
hundreds of millions of people; the
likely demise of the most vulnerable
populations—and at worst, the extinction
of humankind altogether.”
But the
IPCC’s newer models suggest that the
situation is even worse than previously
thought. Based on increased
supercomputing power and sharper
representations of weather systems,
those new climate models—presented at a
press conference in Paris in late
September—reveal
the latest findings of the IPCC’s sixth
assessment report now underway.
The models now show that we are heading
for 7°C by the end of the century if
carbon emissions continue unabated, two
degrees higher than last year’s models.
This means the earth is far more
sensitive to atmospheric carbon than
previously believed.
This suggests that the climate models
we've been using are not too alarmist;
they are consistently too
conservative, and we have only
recently understood how bad the
situation really is.
I
spoke to Dr. Joelle Gergis, a lead
author on the IPCC’s sixth assessment
report, about the new climate models.
Gergis admitted that at least eight of
the new models being produced for the
IPCC by scientists in the US, UK, Canada
and France suggest a much higher climate
sensitivity than older models of 5°C or
warmer. But she pushed back against the
idea that these findings prove the
inevitability of collapse, which she
criticized as outside the domain of
climate science. Rather, the potential
implications of the new evidence are not
yet known.
“Yes, we are facing alarming rates of
change and this raises the likelihood of
abrupt, non-linear changes in the
climate system that may cause tipping
points in the Earth’s safe operating
space,” she said. “But we honestly don’t
know how far away we are from that just
yet. It may also be the case that we can
only detect that we’ve crossed such a
threshold after the fact.”
In an
article published in August in the
Australian magazine The Monthly,
Dr. Gergis
wrote:
“When these results were first released
at a climate modelling workshop in March
this year, a flurry of panicked emails
from my IPCC colleagues flooded my
inbox. What if the models are right? Has
the Earth already crossed some kind of
tipping point? Are we experiencing
abrupt climate change right now?”
Half
the Great Barrier Reef’s coral system
has been wiped out at current global
average temperatures which are now
hovering around 1°C
higher than pre-industrial levels.
Gergis describes this as “catastrophic
ecosystem collapse of the largest living
organism on the planet.” At 1.5°C,
between 70 and 90 percent of
reef-building corals are projected to be
destroyed, and at 2°C, some 99 percent
may disappear: “An entire component of
the Earth’s biosphere—our planetary life
support system—would be eliminated. The
knock-on effects on the 25 percent of
all marine life that depends on coral
reefs would be profound and
immeasurable… The very foundation of
human civilization is at stake.”
But Gergis told me that despite the
gravity of the new models, they do not
prove conclusively that past emissions
will definitely induce collapse within
the next decade.
“While we are undeniably observing rapid
and widespread climate change across the
planet, there is no concrete evidence
that suggests we are facing ‘an
inevitable, near term society collapse
due to climate change,’” she said. “Yes,
we are absolutely hurtling towards
conditions that will create major
instabilities in the climate system, and
time is running out, but I don’t believe
it is a done deal just yet.”
Yet it is
precisely the ongoing absence of strong
global policy that poses the fatal
threat. According to Lund University
climate scientist Wolfgang Knorr, the
new climate models mean that practically
implementing the Paris Accords target of
keeping temperatures at 1.5 degrees is
now extremely difficult. He referred me
to his
new analysis
of the challenge published on the
University of Cumbria’s ILFAS blog,
suggesting that the remaining emissions
budget given by the IPCC “will be
exhausted at the beginning of 2025.” He
also noted that past investment in
fossil-fuel and energy infrastructure
alone will put us well over that budget.
The scale
of the needed decarbonization is so
great and so rapid, according to Tim
Garrett, professor of atmospheric
sciences at the University of Utah, that
civilization would need to effectively
“collapse” its energy consumption to
avoid collapsing due to climate
catastrophe. In a 2012
paper
in Earth System Dynamics, he
concluded therefore that “civilization
may be in a double-bind.”
"We still have time to try and avert the
scale of the disaster, but we must
respond as we would in an emergency"
In a
previous
paper
in Climatic Change, Garrett
calculated that the world would need to
switch to non-carbon renewable energy
sources at a rate of about 2.1 percent a
year just to stabilize emissions. “That
comes out [equivalent] to almost one new
nuclear power plant per day,” Garrett
said. Although he sees this as
fundamentally unrealistic, he concedes
that a crash transition programme might
help: “If society invests sufficient
resources into alternative and new,
non-carbon energy supplies, then perhaps
it can continue growing without
increasing global warming.”
Gergis goes further, insisting that it
is not yet too late: “We still have time
to try and avert the scale of the
disaster, but we must respond as we
would in an emergency. The question is,
can we muster the best of our humanity
in time?”
There is no straightforward answer to
this question. To get there, we need to
understand not just climate science, but
the nature, dynamics, and causes of
civilizational collapse.
Limits to
Growth
One of the most famous scientific
forecasts of collapse was conducted
nearly 50 years ago by a team of
scientists at MIT. Their "Limits to
Growth" (LTG) model, known as "World3,"
captured the interplay between
exponential population and economic
growth, and the consumption of raw
materials and natural resources. Climate
change is an implicit feature of the
model.
LTG implied that business-as-usual would
lead to civilizational breakdown,
sometime between the second decade and
middle of the 21st century, due to
overconsumption of natural resources far
beyond their rate of renewal. This would
escalate costs, diminish returns, and
accelerate environmental waste,
ecosystem damage, and global heating.
With more capital diverted to the cost
of extracting resources, less is left to
invest in industry and other social
goods, driving long-term economic
decline and political unrest.
The
forecast was widely derided when first
published, and its core predictions were
often
wildly misrepresented
by commentators who claimed it had
incorrectly forecast the end of the
world by the year 2000 (it didn’t).
Systems scientist Dennis Meadows had
headed up the MIT team which developed
the ‘World3’ model. Seven years ago, he
updated the original model in light of
new data with co-author Jorgen Randers,
another original World3 team-member.
“For those who respect numbers, we can
report that the highly aggregated
scenarios of World3 still appear… to be
surprisingly accurate,” they wrote in
Limits to Growth: the 30 year update.
“The world is evolving along a path that
is consistent with the main features of
the scenarios in LTG.”
One might
be forgiven for suspecting that the old
MIT team were just blowing their own
horn. But a range of independent
scientific reviews, some with the
backing of various governments, have
repeatedly confirmed that the LTG ‘base
scenario’ of overshoot and collapse has
continued to fit new data. This includes
studies by
Professor Tim Jackson
of the University of Surrey, an
economics advisor to the British
government and Ministry of Defense;
Australia’s federal government
scientific research agency
CSIRO;
Melbourne University’s
Sustainable Society Institute;
and the
Institute and Faculty of Actuaries
in London.
“Collapse is not a very precise term. It
is possible that there would be a
general, drastic, uncontrolled decline
in population, material use, and energy
consumption by 2030 from climate
change," Meadows told me when I asked
him whether the LTG model shines any
light on the risk of imminent collapse.
"But I do not consider it to be a high
probability event,” he said. Climate
change would, however, “certainly
suffice to alter our industrial society
drastically by 2100.” It could take
centuries or millennia for ecosystems to
recover.
But there is a crucial implication of
the LTG model that is often overlooked:
what happens during collapse.
During an actual breakdown, new and
unexpected social dynamics might come
into play which either worsen or even
lessen collapse.
Those dynamics all depend on human
choices. They could involve positive
changes through reform in political
leadership or negative changes such as
regional or global wars.
That’s why modelling what happens
during the onset of collapse is
especially tricky, because the very
process of collapse alters the dynamics
of change.
Growth,
complexity and resource crisis
What if, then, collapse is not
necessarily the end? That’s the view of
Ugo Bardi, of the University of
Florence, who has developed perhaps the
most intriguing new scientific framework
for understanding collapse.
Earlier
this year, Bardi and his team co-wrote
a paper
in the journal BioPhysical Economics
and Resource Quality, drawing on the
work of anthropologist Joseph Tainter at
Utah State University’s Department of
Environment and Society. Tainter’s
seminal book, The Collapse of Complex
Societies, concluded that societies
collapse when their investments in
social complexity reach a point of
diminishing marginal returns.
Tainter studied the fall of the Western
Roman empire, Mayan civilization, and
Chaco civilization. As societies develop
more complex and specialized
bureaucracies to solve emerging
problems, these new layers of
problem-solving infrastructure generate
new orders of problems. Further
infrastructure is then developed to
solve those problems, and the spiral of
growth escalates.
As
each new layer also requires a new
‘energy’ subsidy (greater consumption of
resources), it eventually cannot produce
enough resources to both sustain itself
and resolve the problems generated. The
result is that society collapses to a
new equilibrium by shedding layers of
complex infrastructure amassed in
previous centuries. This descent takes
between decades and centuries.
In his
recent paper,
Bardi used computer models to test how
Tainter’s framework stood-up. He found
that diminishing returns from complexity
were not the main driver of a system’s
decline; rather the decline in
complexity of the system is due to
diminishing returns from exploiting
natural resources.
In
other words, collapse is a result of a
form of endless growth premised on the
unsustainable consumption of resources,
and the new order of increasingly
unresolvable crises this generates.
In
my view, we are already entering a
perfect storm feedback loop of complex
problems that existing systems are too
brittle to solve. The collapse of Syria,
triggered and amplified partly by
climate crisis, did not end in Syria.
Its reverberations have not only helped
destabilize the wider Middle East, but
contributed to the destabilization of
Western democracies.
In January,
a
study
in Global Environment Change
found that the impact of “climatic
conditions” on “drought severity” across
the Middle East and North Africa
amplified the “likelihood of armed
conflict.” The study concluded that
climate change therefore played a
pivotal role in driving the mass asylum
seeking between 2011 and 2015—including
the million or so refugees who arrived
in Europe in 2015 alone, nearly
50 percent of whom
were Syrian. The upsurge of people
fleeing the devastation of their homes
was a gift to the far-right,
exploited
by British, French and other
nationalists campaigning for the
break-up of the European Union, as well
as playing a role in Donald Trump’s
political campaigning around The Wall.
To use
my own terminology,
Earth System Disruption (ESD) is driving
Human System Destabilization (HSD).
Preoccupied with the resulting political
chaos, the Human System becomes even
more vulnerable and incapable of
ameliorating ESD. As ESD thus
accelerates, it generates more HSD. The
self-reinforcing cycle continues, and we
find ourselves in an amplifying feedback
loop of disruption and destabilization.
Beyond
collapse
Is
there a way out of this self-destructive
amplifying feedback loop? Bardi’s work
suggests there might be—that collapse
can pave the way for a new, more viable
form of civilization, whether or not
countries and regions experience
collapses, crises, droughts, famine,
violence, and war as a result of ongoing
climate chaos.
Bardi’s
analysis of Tainter’s work extends the
argument he first explored in his 2017
peer-reviewed
study,
The Seneca Effect: When Growth is
Slow but Collapse is Rapid. The book
is named after the Roman philosopher
Lucius Annaeus Seneca, who once said
that “fortune is of sluggish growth, but
ruin is rapid.”
Bardi examines a wide-range of collapse
cases across human societies (from the
fall of past empires, to financial
crises and large-scale famines), in
nature (avalanches) and through
artificial structures (cracks in metal
objects). His verdict is that collapse
is not a “bug,” but a “varied and
ubiquitous phenomena” with multiple
causes, unfolding differently, sometimes
dangerously, sometimes not. Collapse
also often paves the way for the
emergence of new, evolutionary
structures.
In
an unpublished manuscript titled
Before the Collapse: A Guide to the
Other Side of Growth, due to be
published by science publisher
Springer-Nature next year, Bardi’s
examination of the collapse and growth
of human civilizations reveals that
after collapse, a "Seneca Rebound" often
takes place in which new societies grow,
often at a rate faster than preceding
growth rates.
This is because collapse eliminates
outmoded, obsolete structures, paving
the way for new structures to emerge
which often thrive from the remnants of
the old and in the new spaces that
emerge.
He
thus explains the Seneca Rebound as “as
an engine that propels civilizations
forward in bursts. If this is the case,
can we expect a rebound if the world’s
civilization goes through a new Seneca
Collapse in the coming decades?”
Bardi recognizes that the odds are on a
knife-edge. A Seneca Rebound after a
coming collapse would probably have
different features to what we have seen
after past civilizational collapses and
might still involve considerable
violence, as past new civilizations
often did—or may not happen at all.
"Very little if anything is being done
to stop emissions and the general
destruction of the ecosystem"
On
our current trajectory, he said, “the
effects of the destruction we are
wreaking on the ecosystem could cause
humans to go extinct, the ultimate
Seneca Collapse.” But if we change
course, even if we do not avoid serious
crises, we might lessen the blow of a
potential collapse. In this scenario,
“the coming collapse will be just one
more of the series of previous collapses
that affected human civilizations: it
might lead to a new rebound.”
It
is in this possibility that Bardi sees
the seeds of a new, different kind of
civilization within the collapse of
civilization-as-we-know-it.
I
asked Bardi how soon he thought this
collapse would happen. Although
emphasizing that collapse is not yet
inevitable, he said that a collapse of
some kind within the next decade could
be “very likely” if business-as-usual
continues.
“Very little if anything is being done
to stop emissions and the general
destruction of the ecosystem,” Bardi
said. “So, an ecosystemic collapse is
not impossible within 10 years."
Yet he was also careful to point out
that the worst might be avoided: “On the
other hand, there are many elements
interacting that may change things a
little, a lot, or drastically. We don’t
know how the system may react… maybe the
system would react in a way that could
postpone the worst.”
Release and
renewal
The lesson is that even if collapse is
imminent, all may not be lost. Systems
theorist Jeremy Lent, author of The
Patterning Instinct, draws on the
work of the late University of Florida
ecologist C. S. Holling, whose detailed
study of natural ecosystems led him to
formulate a general theory of social
change known as the adaptive cycle.
Complex
systems, whether in nature or in human
societies, pass through four phases in
their life cycle,
writes
Lent. First is a rapid growth phase of
innovation and opportunity for new
structures; second is a phase of
stability and consolidation, during
which these structures become brittle
and resistant to change; third is a
release phase consisting of breakdown,
generating chaos and uncertainty; the
fourth is reorganization, opening up the
possibility that small, seemingly
insignificant forces might drastically
change the future of the forthcoming new
cycle.
It
is here, in the last two phases, that
the possibility of triggering and
shaping a Seneca Rebound becomes
apparent. The increasing chaos of global
politics, Lent suggests, is evidence
that we are “entering the chaotic
release phase,” where the old order
begins to unravel. At this point, the
system could either regress, or it could
reorganize in a way that enables a new
civilizational rebound. “This is a
crucially important moment in the
system’s life cycle for those who wish
to change the predominant order.”
So
as alarming as the mounting evidence of
the risk of collapse is, it also
indicates that we are moving into a
genuinely new and indeterminate phase in
the life cycle of our current
civilization, during which we have a
radical opportunity to mobilize the
spread of new ideas that can transform
societies.
I
have been tracking the risks of collapse
throughout my career as a journalist and
systems theorist. I could not find any
decisive confirmation that climate
change will inevitably produce near-term
societal collapse.
But the science does not rule this out
as a possibility. Therefore, dismissing
the risk of some sort of
collapse—whether by end of century,
mid-century, or within the next 10
years—contravenes the implications of
the most robust scientific models we
have.
All the scientific data available
suggests that if we continue on our
current course of resource exploitation,
human civilization could begin
experiencing collapse within coming
decades. Exactly where and how such a
collapse process might take off is not
certain; and whether it is already
locked in is as yet unknown. And as
NASA’s Gavin Schmidt told me, local
collapses are already underway.
From Syria to Brexit, the destabilizing
socio-political impacts of ecosystemic
collapse are becoming increasingly
profound, far-reaching and intractable.
In that sense, debating whether or not
near-term collapse is inevitable
overlooks the stark reality that we are
already witnessing climate collapse.
And yet, there remains an almost total
absence of meaningful conversation and
action around this predicament, despite
it being perhaps the most important
issue of our times.
The upshot is that we don’t know for
sure what is round the corner, and we
need better conversations about how to
respond to the range of possibilities.
Preparation for worst-case scenarios
does not require us to believe them
inevitable, but vindicates the adoption
of a rational, risk-based approach
designed to proactively pursue the
admirable goal for Deep Adaptation:
safeguarding as much of society as
possible.
Jem Bendell’s Deep Adaptation approach,
he told me, is not meant to provide
decisive answers about collapse, but to
catalyze conversation and action.
“For the Deep Adaptation groups that I
am involved with, we ask people to agree
that societal collapse is either likely,
inevitable or already unfolding, so that
we can have meaningful engagement upon
that premise,” he said. “Deep Adaptation
has become an international movement
now, with people mobilizing to share
their grief, discuss what to commit to
going forward, become activists, start
growing food, all kinds of things.”
Confronting the specter of collapse, he
insisted is not grounds to give-up, but
to do more. Not later, but right now,
because we are already out of time in
terms of the harm already inflicted on
the planet: “My active and radical hope
is that we will do all kinds of amazing
things to reduce harm, buy time and save
what we can," he said. "Adaptation and
mitigation are part of that agenda. I
also know that many people will act in
ways that create more suffering."
Most of all, the emerging science of
collapse suggests that civilization in
its current form, premised on endless
growth and massive inequalities, is
unlikely to survive this century. It
will either evolve into or be succeeded
by a new configuration, perhaps an
“ecological civilization”, premised on a
fundamentally new relationship with the
Earth and all its inhabitants—or it
will, whether slowly or more abruptly,
regress and contract.
What happens next is still up to us. Our
choices today will not merely write our
own futures, they determine who we are,
and what our descendants will be capable
of becoming. As we look ahead, this
strange new science hints to us at a
momentous opportunity to become agents
of change for an emerging paradigm of
life and society that embraces, not
exploits, the Earth. Because doing so is
now a matter of survival.
This article was originally
published by "Vice"
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