Can a collapse of global civilization be avoided?
It would appear not. - 2022--------via https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3574335/AbstractEnvironmental
problems have contributed to numerous collapses of civilizations in the
past. Now, for the first time, a global collapse appears likely.
Overpopulation, overconsumption by the rich and poor choices of
technologies are major drivers; dramatic cultural change provides the
main hope of averting calamity.Keywords: population, consumption, environment, agriculture, climate, cultureGo to:1. IntroductionVirtually
every past civilization has eventually undergone collapse, a loss of
socio-political-economic complexity usually accompanied by a dramatic
decline in population size [1].
Some, such as those of Egypt and China, have recovered from collapses
at various stages; others, such as that of Easter Island or the Classic
Maya, were apparently permanent [1,2].
All those previous collapses were local or regional; elsewhere, other
societies and civilizations persisted unaffected. Sometimes, as in the
Tigris and Euphrates valleys, new civilizations rose in succession. In
many, if not most, cases, overexploitation of the environment was one
proximate or an ultimate cause [3].But today, for the first time, humanity's global
civilization—the worldwide, increasingly interconnected, highly
technological society in which we all are to one degree or another,
embedded—is threatened with collapse by an array of environmental
problems. Humankind finds itself engaged in what Prince Charles
described as ‘an act of suicide on a grand scale’ [4], facing what the UK's Chief Scientific Advisor John Beddington called a ‘perfect storm’ of environmental problems [5].
The most serious of these problems show signs of rapidly escalating
severity, especially climate disruption. But other elements could
potentially also contribute to a collapse: an accelerating extinction of
animal and plant populations and species, which could lead to a loss of
ecosystem services essential for human survival; land degradation and
land-use change; a pole-to-pole spread of toxic compounds; ocean
acidification and eutrophication (dead zones); worsening of some aspects
of the epidemiological environment (factors that make human populations
susceptible to infectious diseases); depletion of increasingly scarce
resources [6,7], including especially groundwater, which is being overexploited in many key agricultural areas [8]; and resource wars [9].
These are not separate problems; rather they interact in two gigantic
complex adaptive systems: the biosphere system and the human
socio-economic system. The negative manifestations of these interactions
are often referred to as ‘the human predicament’ [10], and determining how to prevent it from generating a global collapse is perhaps the foremost challenge confronting humanity.The
human predicament is driven by overpopulation, overconsumption of
natural resources and the use of unnecessarily environmentally damaging
technologies and socio-economic-political arrangements to service Homo sapiens’ aggregate consumption [11–17].
How far the human population size now is above the planet's long-term
carrying capacity is suggested (conservatively) by ecological footprint
analysis [18–20]. It shows that to support today's
population of seven billion sustainably (i.e. with business as usual,
including current technologies and standards of living) would require
roughly half an additional planet; to do so, if all citizens of Earth
consumed resources at the US level would take four to five more Earths.
Adding the projected 2.5 billion more people by 2050 would make the
human assault on civilization's life-support systems disproportionately
worse, because almost everywhere people face systems with nonlinear
responses [11,21–23],
in which environmental damage increases at a rate that becomes faster
with each additional person. Of course, the claim is often made that
humanity will expand Earth's carrying capacity dramatically with
technological innovation [24],
but it is widely recognized that technologies can both add and subtract
from carrying capacity. The plough evidently first expanded it and now
appears to be reducing it [3]. Overall, careful analysis of the prospects does not provide much confidence that technology will save us [25] or that gross domestic product can be disengaged from resource use [26].Go to:2. Do current trends portend a collapse?What is the likelihood of this set of interconnected predicaments [27] leading to a global collapse in this century? There have been many definitions and much discussion of past ‘collapses’ [1,3,28–31],
but a future global collapse does not require a careful definition. It
could be triggered by anything from a ‘small’ nuclear war, whose
ecological effects could quickly end civilization [32],
to a more gradual breakdown because famines, epidemics and resource
shortages cause a disintegration of central control within nations, in
concert with disruptions of trade and conflicts over increasingly scarce
necessities. In either case, regardless of survivors or replacement
societies, the world familiar to anyone reading this study and the
well-being of the vast majority of people would disappear.How
likely is such a collapse to occur? No civilization can avoid collapse
if it fails to feed its population. The world's success so far, and the
prospective ability to feed future generations at least as well, has
been under relatively intensive discussion for half a century [33–40].
Agriculture made civilization possible, and over the last 80 years or
so, an industrial agricultural revolution has created a
technology-dependent global food system. That system, humanity's single
biggest industry, has generated miracles of food production. But it has
also created serious long-run vulnerabilities, especially in its
dependence on stable climates, crop monocultures, industrially produced
fertilizers and pesticides, petroleum, antibiotic feed supplements and
rapid, efficient transportation.Despite those food
production miracles, today at least two billion people are hungry or
poorly nourished. The Food and Agriculture Organization estimates that
increasing food production by some 70 per cent would be required to feed
a 35 per cent bigger and still growing human population adequately by
2050 [41]. What are the prospects that H. sapiens
can produce and distribute sufficient food? To do so, it probably will
be necessary to accomplish many or all of the following tasks: severely
limit climate disruption; restrict expansion of land area for
agriculture (to preserve ecosystem services); raise yields where
possible; put much more effort into soil conservation [3];
increase efficiency in the use of fertilizers, water and energy; become
more vegetarian; grow more food for people (not fuel for vehicles);
reduce food wastage; stop degradation of the oceans and better regulate
aquaculture; significantly increase investment in sustainable
agricultural and aquacultural research; and move increasing equity and
feeding everyone to the very top of the policy agenda.Most
of these long-recommended tasks require changes in human behaviour thus
far elusive. The problem of food wastage and the need for more and
better agricultural research have been discussed for decades. So have
‘technology will save us’ schemes such as building ‘nuclear
agro-industrial complexes’ [42],
where energy would be so cheap that it could support a new kind of
desert agriculture in ‘food factories’, where crops would be grown on
desalinated water and precisely machine fertilized. Unhappily,
sufficiently cheap energy has never been produced by nuclear power to
enable large-scale agriculture to move in that direction. Nor has
agriculture moved towards feeding people protein extracted from leaves
or bacteria grown on petroleum [43,
pp. 95–112]. None of these schemes has even resulted in a coordinated
development effort. Meanwhile, growing numbers of newly well-off people
have increased demand for meat [44], thereby raising global demand for feedgrains.Perhaps
even more critical, climate disruption may pose insurmountable
biophysical barriers to increasing crop yields. Indeed, if humanity is
very unlucky with the climate, there may be reductions in yields of
major crops [45], although near-term this may be unlikely to affect harvests globally [46]. Nonetheless, rising temperatures already seem to be slowing previous trends of increasing yields of basic grains [45,47], and unless greenhouse gas emissions are dramatically reduced, dangerous anthropogenic climate change [48]
could ravage agriculture. Also, in addition to falling yields from many
oceanic fish stocks because of widespread overfishing [49], warming and acidification of the oceans threaten the protein supply of some of the most nutritionally vulnerable people [50], especially those who cannot afford to purchase farmed fish.Unfortunately,
the agricultural system has complex connections with all the chief
drivers of environmental deterioration. Agriculture itself is a major
emitter of greenhouse gases and thus is an important cause of climate
disruption as well as being exceptionally vulnerable to its
consequences. More than a millennium of change in temperature and
precipitation patterns is apparently now entrained [51],
with the prospect of increasingly severe storms, droughts, heat waves
and floods, all of which seem already evident and all of which threaten
agricultural production.Land is an essential resource
for farming, and one facing multiple threats. In addition to the serious
and widespread problems of soil degradation, sea-level rise (the most
certain consequence of global warming) will take important areas out of
production either by inundating them (a 1 m rise would flood 17.5% of
Bangladesh [52]),
exposing them to more frequent storm surges, or salinizing coastal
aquifers essential for irrigation water. Another important problem for
the food system is the loss of prime farmland to urbanization, a trend
that seems certain to accelerate [53] as population growth steadily erodes the per capita supply of farmland.The
critical importance of substantially boosting the inadequate current
action on the demographic problem can be seen in the time required to
change the trajectory of population growth humanely and sensibly. We
know from such things as the World War II mobilizations that many
consumption patterns can be altered dramatically within a year, given
appropriate incentives [54].
If food shortages became acute, then a rapid reaction would ensue as
hunger became much more widespread. Food prices would rise, and diets
would temporarily change (e.g. the number of meals consumed per day or
amount of meat consumed) to compensate the shortage. Over the long term,
however, expanding the global food supply and distributing it more
equitably would be a slow and difficult process. Even though a major
famine might well provoke investment in long-needed improvements in food
production and distribution, they would take time to plan, test and
implement.Furthermore, agriculture is
a leading cause of losses of biodiversity and thus of the critical
ecosystem services supplied to agriculture itself (e.g. pollination,
pest control, soil fertility, climate stability) and other human
enterprises. Farming is also a principal source of global toxification,
as has been clear since the days of Carson [55], exposing the human population to myriad subtle poisons. These pose further potential risks to food production.Go to:3. What needs to be done to avoid a collapse?The
threat from climate disruption to food production alone means that
humanity's entire system for mobilizing energy needs to be rapidly
transformed. Warming must be held well below a potential 5°C rise in
global average temperature, a level that could well bring down
civilization [56].
The best estimate today may be that, failing rapid concerted action,
the world is already committed to a 2.4°C increase in global average
temperature [57].
This is significantly above the 2°C estimated a decade ago by climate
scientists to be a ‘safe’ limit, but now considered by some analysts to
be too dangerous [58,59],
a credible assessment, given the effects seen already before reaching a
one degree rise. There is evidence, moreover, that present models
underestimate future temperature increase by overestimating the extent
that growth of vegetation can serve as a carbon sink [60] and underestimating positive feedbacks [61].Many
complexities plague the estimation of the precise threats of
anthropogenic climate disruption, ranging from heat deaths and spread of
tropical diseases to sea-level rise, crop failures and violent storms.
One key to avoiding a global collapse, and thus an area requiring great
effort and caution is avoiding climate-related mass famines. Our
agricultural system evolved in a geological period of relatively
constant and benign climate and was well attuned to twentieth-century
conditions. That alone is cause for substantial concern as the planet's
climates rapidly shift to new, less predictable regimes. It is essential
to slow that process. That means dramatically transforming much of the
existing energy mobilization infrastructure [62] and changing human behaviour to make the energy system much more efficient. This is possible; indeed, sensible plans for doing it have been put forward [63,64],
and some progress has been made. The central challenge, of course, is
to phase out more than half of the global use of fossil fuels by 2050 in
order to forestall the worst impacts of climate disruption, a challenge
the latest International Energy Agency edition of World Energy Outlook
makes look more severe [65].
This highlights another dilemma. Fossil fuels are now essential to
agriculture for fertilizer and pesticide manufacture, operation of farm
machinery, irrigation (often wasteful), livestock husbandry, crop
drying, food storage, transportation and distribution. Thus, the
phase-out will need to include at least partial substitution of
non-fossil fuels in these functions, and do so without greatly
increasing food prices.Unfortunately, essential steps
such as curbing global emissions to peak by 2020 and reducing them to
half of present levels by 2050 [66]
are extremely problematic economically and politically. Fossil fuel
companies would have to leave most of their proven reserves in the
ground, thus destroying much of the industry's economic value [67]. Because the ethics of some businesses include knowingly continuing lethal but profitable activities [68],
it is hardly surprising that interests with large financial stakes in
fossil fuel burning have launched a gigantic and largely successful
disinformation campaign in the USA to confuse people about climate
disruption [69,70] and block attempts to deal with it [71].One recurrent theme in analyses of the food problem is the need for closing ‘yield gaps’ [72–74].
That means raising yields in less productive systems to those typical
of industrial agriculture. But climatic conditions may change
sufficiently that those industrial high yields can themselves no longer
be sustained [45].
Thus, reducing the chances of a collapse calls for placing much more
effort into genetic and ecological research related to agriculture [75]
and adopting already known environmental-friendly techniques, even
though that may require trading off immediate corporate profits for
social benefits or long-term sustainability [3].Rationalizing
energy mobilization alone may not be enough to be enough to maintain
agricultural production, let alone allow its great expansion. Human
water-handling infrastructure will have to be re-engineered for
flexibility to bring water to crops in an environment of constantly
changing precipitation patterns [51].
This is critical, for although today only about 15 per cent of
agricultural land is irrigated, it provides some 40 per cent of the
grain crop yield. It seems likely that farming areas now rain-fed may
someday need to be irrigated, whereas irrigation could become
superfluous elsewhere, and both could change more or less continually.
For this and many other reasons, the global food system will need to
quickly evolve an unprecedented flexibility, never before even
contemplated.One factor making the
challenges more severe is the major participation in the global system
of giant nations whose populations have not previously enjoyed the
fossil energy abundance that brought Western countries and Japan to
positions of affluence. Now they are poised to repeat the West's energy
‘success’, and on an even greater scale. India alone, which recently
suffered a gigantic blackout affecting 300 million people, is planning
to bring 455 new coal plants on line. Worldwide more than 1200 plants
with a total installed capacity of 1.4 million megawatts are planned [76],
much of that in China, where electricity demand is expected to
skyrocket. The resultant surge in greenhouse gases will interact with
the increasing diversion of grain to livestock, stimulated by the desire
for more meat in the diets of Indians, Chinese and others in a growing
global middle class.Go to:4. Dealing with problems beyond food supplyAnother
possible threat to the continuation of civilization is global
toxification. Adverse symptoms of exposure to synthetic chemicals are
making some scientists increasingly nervous about effects on the human
population [77–79].
Should a global threat materialize, however, no planned mitigating
responses (analogous to the ecologically and politically risky
‘geoengineering’ projects often proposed to ameliorate climate
disruption [80]) are waiting in the wings ready for deployment.Much
the same can be said about aspects of the epidemiological environment
and the prospect of epidemics being enhanced by rapid population growth
in immune-weakened societies, increased contact with animal reservoirs,
high-speed transport and the misuse of antibiotics [81].
Nobel laureate Joshua Lederberg had great concern for the epidemic
problem, famously stating, ‘The survival of the human species is not a
preordained evolutionary program’ [82,
p. 40]. Some precautionary steps that should be considered include
forbidding the use of antibiotics as growth stimulators for livestock,
building emergency stocks of key vaccines and drugs (such as Tamiflu),
improving disease surveillance, expanding mothballed emergency medical
facilities, preparing institutions for imposing quarantines and, of
course, moving as rapidly as possible to humanely reduce the human
population size. It has become increasingly clear that security has many
dimensions beyond military security [83,84] and that breaches of environmental security could risk the end of global civilization.But
much uncertainty about the human ability to avoid a collapse still
hinges on military security, especially whether some elements of the
human predicament might trigger a nuclear war. Recent research indicates
that even a regional-scale nuclear conflict, as is quite possible
between India and Pakistan, could lead to a global collapse through
widespread climatic consequences [32].
Triggers to conflict beyond political and religious strife easily could
include cross-border epidemics, a need to gain access to food supplies
and farmland, and competition over other resources, especially
agricultural water and (if the world does not come to its energy senses)
oil. Finding ways to eliminate nuclear weapons and other instruments of
mass destruction must move even higher on civilization's agenda [85], because nuclear war would be the quickest and surest route to a collapse [86].In
thinking about the probability of collapse, one must obviously consider
the social disruptions associated with elements of the predicament.
Perhaps at the top of the list should be that of environmental refugees [87]. Recent predictions are that environmental refugees could number 50 million by 2020 [88].
Severe droughts, floods, famines and epidemics could greatly swell that
number. If current ‘official’ predictions of sea-level rise are low (as
many believe they are), coastal inundations alone could generate
massive human movements; a 1 m rise would directly affect some 100
million people, whereas a 6 m rise would displace more than 400 million [89].
Developing a more comprehensive system of international governance with
institutions planning to ameliorate the impacts of such catastrophes
would be a major way to reduce the odds of collapse.Go to:5. The role of scienceThe scientific community has repeatedly warned humanity in the past of its peril [90–102], and the earlier warnings [93,103–107] about the risks of population expansion and the ‘limits to growth’ have increasingly been shown to be on the right track [108–111] (but see Hayes [17]). The warnings continue [109,112–119].
Yet many scientists still tend to treat population growth as an
exogenous variable, when it should be considered an endogenous
one—indeed, a central factor [120].
Too many studies asking ‘how can we possibly feed 9.6 billion people by
2050?’ should also be asking ‘how can we humanely lower birth rates far
enough to reduce that number to 8.6?’ To our minds, the fundamental
cure, reducing the scale of the human enterprise (including the size of
the population) to keep its aggregate consumption within the carrying
capacity of Earth [121],
is obvious but too much neglected or denied. There are great social and
psychological barriers in growthmanic cultures to even considering it.
This is especially true because of the ‘endarkenment’—a rapidly growing
movement towards religious orthodoxies that reject enlightenment values
such as freedom of thought, democracy, separation of church and state,
and basing beliefs and actions on empirical evidence. They are manifest
in dangerous trends such as climate denial, failure to act on the loss
of biodiversity and opposition to condoms (for AIDS control) as well as
other forms of contraception [122]. If ever there was a time for evidence-based (as opposed to faith-based) risk reduction strategies [123], it is now.How
can scientists do more to reduce the odds of a collapse? Both natural
and social scientists should put more effort into finding the best ways
of accomplishing the necessary re-modelling of energy and water
infrastructure. They should develop better ways of evaluating and
regulating the use of synthetic chemicals, a problem that might abate
somewhat as availability of their fossil fuel sources fades (even though
only about 5% of oil production flows into petrochemical production).
The protection of Earth's remaining biodiversity (especially the crucial
diversity of populations [124,125]) must take centre stage for both scientific specialists and, through appropriate education, the public [126,127].
Scientists must continually call attention to the need to improve the
human epidemiological environment, and for control and eventual
elimination of nuclear, chemical and biological weapons. Above all, they
should expand efforts to understand the mechanisms through which
cooperation evolves [128], because avoiding collapse will require unusual levels of international cooperation.Is
it too late for the global scientific community to collect itself and
start to deal with the nexus of the two complex adaptive systems [129]
and then help generate the necessary actions to move towards
sustainability? There are certainly many small-scale science-based
efforts, often local, that can provide hope if scaled up [121].
For example, environmental non-govenmental organizations and others are
continually struggling to halt the destruction of elements of
biodiversity (and thus, in some cases, of vital ecosystem services [7]),
often with success. In the face of the building extinction crisis, they
may be preserving nuclei from which Earth's biota and humanity's
ecosystem services, might eventually be regenerated. And some positive
efforts are scaling up. China now has some 25 per cent of its land in ecosystem function conservation areas [130] designed to protect both natural capital and human well-being. The Natural Capital Project [131]
is helping improve the management of these areas. This is good news,
but in our view, many too few scientists are involved in the efforts
needed, especially in re-orienting at least part of their research
towards mitigating the predicament and then bringing their results to
the policy front.Go to:6. The need for rapid social/political changeUntil
very recently, our ancestors had no reason to respond genetically or
culturally to long-term issues. If the global climate were changing
rapidly for Australopithecus or even ancient Romans, then they
were not causing it and could do nothing about it. The forces of genetic
and cultural selection were not creating brains or institutions capable
of looking generations ahead; there would have been no selection
pressures in that direction. Indeed, quite the opposite, selection
probably favoured mechanisms to keep perception of the environmental
background steady so that rapid changes (e.g. leopard approaching) would
be obvious [132,
pp. 135–136]. But now slow changes in that background are the most
lethal threats. Societies have a long history of mobilizing efforts,
making sacrifices and changes, to defeat an enemy at the gates, or even
just to compete more successfully with a rival. But there is not much
evidence of societies mobilizing and making sacrifices to meet gradually
worsening conditions that threaten real disaster for future
generations. Yet that is exactly the sort of mobilization that we
believe is required to avoid a collapse.Perhaps the
biggest challenge in avoiding collapse is convincing people, especially
politicians and economists, to break this ancient mould and alter their
behaviour relative to the basic population-consumption drivers of
environmental deterioration. We know that simply informing people of the
scientific consensus on a serious problem does not ordinarily produce
rapid changes in institutional or individual behaviour. That was amply
demonstrated in the case of cigarettes [68], air pollution and other environmental problems [69] and is now being demonstrated in the obesity epidemic [133] as well as climate disruption.Obvious
parallels exist regarding reproduction and overconsumption, which are
especially visible in what amounts to a cultural addiction to continued
economic growth among the already well-off [134].
One might think that the mathematics of compound interest would have
convinced everyone long ago that growth of an industrialized economy at
3.5 per cent annually cannot long continue. Unfortunately, most
‘educated’ people are immersed in a culture that does not recognize
that, in the real world, a short history (a few centuries) of
exponential growth does not imply a long future of such growth.Besides
focusing their research on ways to avoid collapse, there is a need for
natural scientists to collaborate with social scientists, especially
those who study the dynamics of social movements. Such collaborations
could develop ways to stimulate a significant increase in popular
support for decisive and immediate action on the predicament.
Unfortunately, awareness among scientists that humanity is in deep
trouble has not been accompanied by popular awareness and pressure to
counter the political and economic influences implicated in the current
crisis. Without significant pressure from the public demanding action,
we fear there is little chance of changing course fast enough to
forestall disaster.The needed pressure, however, might
be generated by a popular movement based in academia and civil society
to help guide humanity towards developing a new multiple intelligence [135],
‘foresight intelligence’ to provide the long-term analysis and planning
that markets cannot supply. Foresight intelligence could not only
systematically look ahead but also guide cultural changes towards
desirable outcomes such as increased socio-economic resilience. Helping
develop such a movement and foresight intelligence are major challenges
facing scientists today, a cutting edge for research that must slice
fast if the chances of averting a collapse are to be improved.If
foresight intelligence became established, many more scientists and
policy planners (and society) might, for example, understand the
demographic contributions to the predicament [136],
stop treating population growth as a ‘given’ and consider the
nutritional, health and social benefits of humanely ending growth well
below nine billion and starting a slow decline. This would be a
monumental task, considering the momentum of population growth.
Monumental, but not impossible if the political will could be generated
globally to give full rights, education and opportunities to women, and
provide all sexually active human beings with modern contraception and
backup abortion. The degree to which those steps would reduce fertility
rates is controversial [137–139], but they are a likely win-win for societies [140].Obviously,
especially with the growing endarkenment, there are huge cultural and
institutional barriers to establishing such policies in some parts of
the world. After all, there is not a single nation where women are truly
treated as equal to men. Despite that, the population driver should not
be ignored simply because limiting overconsumption can, at least in
theory, be achieved more rapidly. The difficulties of changing
demographic trajectories mean that the problem should have been
addressed sooner, rather than later. That halting population growth
inevitably leads to changes in age structure is no excuse for bemoaning
drops in fertility rates, as is common in European government circles [141].
Reduction of population size in those over-consuming nations is a very
positive trend, and sensible planning can deal with the problems of
population aging [142].While
rapid policy change to head off collapse is essential, fundamental
institutional change to keep things on track is necessary as well. This
is especially true of educational systems, which today fail to inform
most people of how the world works and thus perpetuate a vast culture
gap [54].
The academic challenge is especially great for economists, who could
help set the background for avoiding collapse by designing steady-state
economic systems [107,134,143],
and along the way destroying fables such as ‘growth can continue
forever if it's in service industries’, or ‘technological innovation
will save us’. Issues such as the importance of comparative advantage
under current global circumstances [144], the development of new models that better reflect the irrational behaviour of individuals and groups [145],
reduction of the worship of ‘free’ markets that infests the discipline,
and tasks such as making information more symmetrical, moving towards
sustainability and enhancing equity (including redistribution) all require re-examination. In that re-examination, they would be following the lead of distinguished economists [146–148] in dealing with the real world of biophysical constraints and human well-being.At the global level, the loose network of agreements that now tie countries together [149,150],
developed in a relatively recent stage of cultural evolution since
modern nation states appeared, is utterly inadequate to grapple with the
human predicament. Strengthening global environmental governance [151] and addressing the related problem of avoiding failed statehood [152]
are tasks humanity has so far refused to tackle comprehensively even as
cultural evolution in technology has rendered the present international
system (as it has educational systems) obsolete. Serious global
environmental problems can only be solved and a collapse avoided with an
unprecedented level of international cooperation [122].
Regardless of one's estimate of civilization's potential longevity, the
time to start restructuring the international system is right now. If
people do not do that, nature will restructure civilization for us.Similarly,
widely based cultural change is required to reduce humanely both
population size and overconsumption by the rich. Both go against
cultural norms, and, as long feared [153],
the overconsumption norm has understandably been adopted by the
increasingly rich subpopulations of developing nations, notably India
and China. One can be thrilled by the numbers of people raised from
poverty while being apprehensive about the enormous and possibly lethal
environmental and social costs that may eventually result [154,155].
The industrial revolution set civilization on the road to collapse,
spurring population growth, which contributed slightly more than
overconsumption to environmental degradation [136]. Now population combined with affluence growth may finish the job.Needless
to say, dealing with economic and racial inequities will be critically
important in getting large numbers of people from culturally diverse
groups [156] to focus their minds on solving the human predicament, something globalization should help [157]. These tasks will be pursued, along with an emphasis on developing ‘foresight intelligence’, by the nascent Millennium Alliance for Humanity and the Biosphere (the MAHB; http://mahb.stanford.edu).
One of its central goals is to try to accelerate change towards
sustainability. Since simply giving the scientific facts to the public
will not do it, among other things, this means finding frames and
narratives to convince the public of the need to make changes.We know that societies can evolve fundamentally and unexpectedly [158, p. 334], as was dramatically demonstrated by the collapse of communist regimes in Europe in 1989 [159].
Rather than tinkering around the edges and making feeble or empty
gestures towards one or another of the interdependent problems we face,
we need a powerful and comprehensive approach. In addressing climate
change, for instance, developing nations need to be convinced that they
(along with the rest of the world) cannot afford (and do not need) to
delay action while they ‘catch up’ in development. Indeed, development
on the old model is counterproductive; they have a great opportunity to
pioneer new approaches and technologies. All nations need to stop
waiting for others to act and be willing to do everything they can to
mitigate emissions and hasten the energy transition, regardless of what
others are doing.With climate and
many other global environmental problems, polycentric solutions may be
more readily found than global ones. Complex, multi-level systems may be
better able to cope with complex, multi-level problems [160],
and institutional change is required at many levels in many polities.
What scientists understand about cultural evolution suggests that, while
improbable, it may be possible to move cultures in such directions [161,162].
Whether solutions will be global or polycentric, international
negotiations will be needed, existing international agencies that deal
with them will need strengthening, and new institutions will need to be
formed.Go to:7. ConclusionsDo
we think global society can avoid a collapse in this century? The
answer is yes, because modern society has shown some capacity to deal
with long-term threats, at least if they are obvious or continuously
brought to attention (think of the risks of nuclear conflict). Humanity
has the assets to get the job done, but the odds of avoiding collapse
seem small because the risks are clearly not obvious to most people and
the classic signs of impending collapse, especially diminishing returns
to complexity [28],
are everywhere. One central psychological barrier to taking dramatic
action is the distribution of costs and benefits through time: the costs
up front, the benefits accruing largely to unknown people in the
future. But whether we or more optimistic observers [17,163]
are correct, our own ethical values compel us to think the benefits to
those future generations are worth struggling for, to increase at least
slightly the chances of avoiding a dissolution of today's global
civilization as we know it.Go to:AcknowledgementsWe
are especially grateful to Joan Diamond, Executive Director of the
MAHB, for her ideas on foresight intelligence, and to the Beijer
Institute of Ecological Economics for two decades of provocative
discussions on topics related to this paper. This paper has benefited
from comments from Ken Arrow, Scott Barrett, Andy Beattie, Dan
Blumstein, Corey Bradshaw, Greg Bratman, Paul Brest, Jim Brown, Bob
Brulle, Gretchen Daily, Lisa Daniel, Timothy Daniel, Partha Dasgupta,
Nadia Diamond-Smith, Tom Dietz, Anantha Duraiappah, Riley Dunlap, Walter
Falcon, Marc Feldman, Rachelle Gould, Larry Goulder, John Harte, Mel
Harte, Ursula Heise, Tad Homer-Dixon, Bob Horn, Danny Karp, Don Kennedy,
Michael Klare, Simon Levin, Jack Liu, David Lobell, Doug McAdam, Chase
Mendenhall, Hal Mooney, Fathali Moghaddam, Dennis Pirages, Graham Pyke,
Gene Rosa, Lee Ross, Jose Sarukhan, Kirk Smith, Sarah Soule, Chris
Turnbull and Wren Wirth. Two of the best and most thorough anonymous
reviewers we have ever encountered helped us improve the manuscript. The
work was supported by Peter and Helen Bing and the Mertz Gilmore
Foundation.Go to:Authors' profilePaul Ehrlich
is a Professor of Biology and President of the Center for Conservation
Biology at Stanford University, and Adjunct Professor at the University
of Technology, Sydney. His research interests are in the ecology and
evolution of natural populations of butterflies, reef fishes, birds and
human beings.Anne Ehrlich is a Senior Research Scientist in Biology at Stanford and focuses her research on policy issues related to the environment.Go to:References1. Diamond J.
2005.
Collapse: how societies choose to fail or succeed. New York, NY: Viking [Google Scholar]2. Morris I.
2011.
Why the west rules for now: the patterns of history, and what they reveal about the future. New York, NY: Picador [Google Scholar]3. Montgomery DR.
2012.
Dirt: the erosion of civilizations. Berkeley, CA: University of California Press [Google Scholar]4. Brown J.
2012.
Mankind must go green or die, says Prince Charles. The Independent (London). See http://ind.pn/R5WZgl (accessed 23 November).5. Sample I.
2009.
World faces ‘perfect storm’ of problems by 2030, chief scientist to warn. The Guardian. See http://www.guardian.co.uk/science/2009/mar/18/perfect-storm-john-beddington-energy-food-climate.6. Klare MT.
2012.
The race for what‘s left: the global scramble for the world‘s last resources. New York, NY: Metropolitan Books [Google Scholar]7. Heinberg R.
2007.
Peak everything: waking up to the century of declines. Gabriola Island, BC: New Society Publishers [Google Scholar]8. Gleeson TT, Wada YY, Bierkens MFP, van Beek LPH.
2012.
Water balance of global aquifers revealed by groundwater footprint. Nature
488, 197–20010.1038/nature11295 (doi:10.1038/nature11295) [PubMed] [CrossRef] [Google Scholar]9. Klare MT.
2001.
Resource wars: the new landscape of global conflict. New York, NY: Henry Holt [Google Scholar]10. Ehrlich PR, Ehrlich AH.
2012.
Solving the human predicament. Int. J. Environ. Stud.
69, 557–56510.1080/00207233.2012.693281 (doi:10.1080/00207233.2012.693281) [CrossRef] [Google Scholar]11. Ehrlich PR, Holdren J.
1971.
Impact of population growth. Science
171, 1212–121710.1126/science.171.3977.1212 (doi:10.1126/science.171.3977.1212) [PubMed] [CrossRef] [Google Scholar]12. Holdren JP, Ehrlich PR.
1974.
Human population and the global environment. Am. Sci.
62, 282–292 [PubMed] [Google Scholar]13. Dietz T, Rosa E.
1994.
Rethinking the environmental impacts of population, affluence and technology. Hum. Ecol. Rev.
1, 277–300 [Google Scholar]14. Rosa EA, York R, Dietz T.
2004.
Tracking the anthropogenic drivers of ecological impacts. Ambio
333, 509–512 [PubMed] [Google Scholar]15. Dietz T, Rosa EA, York R.
2010.
Human driving forces of global change: dominant perspectives. In Human footprints on the global environment: threats to sustainability (eds Rosa EA, Diekmann A, Dietz T, Jaeger CC.), pp. 83–134
Cambridge, MA: MIT Press [Google Scholar]16. Alcott B.
2010.
Impact caps: why population, affluence and technology strategies should be abandoned. J. Cleaner Prod.
18, 552–56010.1016/j.jclepro.2009.08.001 (doi:10.1016/j.jclepro.2009.08.001) [CrossRef] [Google Scholar]17. Hayes B.
2012.
Computation and the human predicament. Am. Sci.
100, 186–19110.1511/2012.96.186 (doi:10.1511/2012.96.186) [CrossRef] [Google Scholar]18. Wackernagel M, Rees W.
1996.
Our ecological footprint: reducing human impact on the Earth. Gabriola Island, BC: New Society Publishers [Google Scholar]19. Global Footprint Network
2012.
World footprint: do we fit the planet. See http://www.footprintnetwork.org/en/index.php/GFN/page/world_footprint/20. Rees WE.
In press
Ecological footprint, concept of. In Encyclopedia of biodiversity (ed. Levin S.), 2nd edn.
San Diego, CA: Academic Press [Google Scholar]21. Harte J.
2007.
Human population as a dynamic factor in environmental degradation. Popul. Environ.
28, 223–23610.1007/s11111-007-0048-3 (doi:10.1007/s11111-007-0048-3) [CrossRef] [Google Scholar]22. Liu J, Daily G, Ehrlich PR, Luck G.
2003.
Effects of household dynamics on resource consumption and biodiversity. Nature
421, 530–53310.1038/nature01359 (doi:10.1038/nature01359) [PubMed] [CrossRef] [Google Scholar]23. Yu E, Liu J.
2007.
Environmental impacts of divorce. Proc. Natl Acad. Sci. USA
104, 20 629–20 63410.1073/pnas.0707267104 (doi:10.1073/pnas.0707267104) [PMC free article] [PubMed] [CrossRef] [Google Scholar]24. Rosner L.
2004.
The technological fix: how people use technology to create and solve problems. New York, NY: Routledge [Google Scholar]25. Huesemann M, Huesemann J.
2012.
Techno-fix: why technology won't save us or the environment. Gabriola Island, BC: New Society Publishers [Google Scholar]26. Brown JH, et al.
2011.
Energetic limits to economic growth. BioScience
61, 19–2610.1525/bio.2011.61.1.7 (doi:10.1525/bio.2011.61.1.7) [CrossRef] [Google Scholar]27. Liu J, et al.
2007.
Complexity of coupled human and natural systems. Science
317, 1513–151610.1126/science.1144004 (doi:10.1126/science.1144004) [PubMed] [CrossRef] [Google Scholar]28. Tainter JA.
1988.
The collapse of complex societies. Cambridge, UK: Cambridge University Press [Google Scholar]29. McAnany PA, Yoffee N.
2010.
Questioning collapse: human resilience, ecological vulnerability, and the aftermath of empire. New York, NY: Cambridge University Press [Google Scholar]30. Tainter J.
2006.
Archaeology of overshoot and collapse. Ann. Rev. Anthropol.
35, 9–7410.1146/annurev.anthro.35.081705.123136 (doi:10.1146/annurev.anthro.35.081705.123136) [CrossRef] [Google Scholar]31. Butzer KW, Endfield GH.
2012.
Critical perspectives on historical collapse. Proc. Natl Acad. Sci. USA
109, 3628–363110.1073/pnas.1114772109 (doi:10.1073/pnas.1114772109) [PMC free article] [PubMed] [CrossRef] [Google Scholar]32. Toon O, Robock A, Turco RP, Bardeen C, Oman L, Stenchikov G.
2007.
Consequences of regional-scale nuclear conflicts. Science
315, 1224–122510.1126/science.1137747 (doi:10.1126/science.1137747) [PubMed] [CrossRef] [Google Scholar]33. Paddock W, Paddock P.
1967.
Famine: 1975! Boston, MA: Little Brown & Co [Google Scholar]34. Brown LR.
1968.
Seeds of change: the green revolution and development in the 1970s. New York, NY: Frederick A. Praeger [Google Scholar]35. Bardach J.
1968.
Harvest of the sea. New York, NY: Harper and Row [Google Scholar]36. Borgstrom G.
1969.
Too many. Toronto, Canada: Collier-Macmillan [Google Scholar]37. Frankel O, Agble WK, Harlan JB.
1969.
Genetic dangers in the green revolution. Areas (FAO)
2, 35–37 [Google Scholar]38. Pirie NW.
1969.
Food resources, conventional and novel. Baltimore, MD: Penguin [Google Scholar]39. Ryther JH.
1969.
Photosynthesis and fish production in the sea. Science
166, 72–7610.1126/science.166.3901.72 (doi:10.1126/science.166.3901.72) [PubMed] [CrossRef] [Google Scholar]40. Daily GC, Ehrlich PR.
1990.
An exploratory model of the impact of rapid climate change on the world food situation. Proc. R. Soc. Lond. B
241, 232–24410.1098/rspb.1990.0091 (doi:10.1098/rspb.1990.0091) [PubMed] [CrossRef] [Google Scholar]41. Food and Agriculture Organization (FAO)
2009.
How to feed the world in 2050. See http://www.fao.org/fileadmin/templates/wsfs/docs/expert_paper/How_to_Feed_the_World_in_2050.pdf. Rome, Italy [Google Scholar]42. Weinberg AM.
1969.
Nuclear energy and the agro-industrial complex. Nature
222, 17–2110.1038/222017a0 (doi:10.1038/222017a0) [CrossRef] [Google Scholar]43. Ehrlich PR, Ehrlich AH.
1970.
Population, resources, environment: issues in human ecology. San Francisco, CA: W.H. Freeman and Co [Google Scholar]44. York R, Gossard MH.
2004.
Cross-national meat and fish consumption: exploring the effects of modernization and ecological context. Ecol. Econ.
48, 293–30210.1016/j.ecolecon.2003.10.009 (doi:10.1016/j.ecolecon.2003.10.009) [CrossRef] [Google Scholar]45. Lobell DB, Schlenker W, Costa-Roberts J.
2011.
Climate trends and global crop production since 1980. Science
333, 616–62010.1126/science.1204531 (doi:10.1126/science.1204531) [PubMed] [CrossRef] [Google Scholar]46. Lobell DB, Gourdji SM.
In press.
The influence of climate change on global crop productivity. Plant Physiol. [PMC free article] [PubMed] [Google Scholar]47. Lobell DB, Field CB.
2007.
Global scale climate–crop yield relationships and the impacts of recent warming. Environ. Res. Lett.
2, 014002.10.1088/1748-9326/2/1/014002 (doi:10.1088/1748-9326/2/1/014002) [CrossRef] [Google Scholar]48. Hansen J, et al.
2012.
Scientific case for avoiding dangerous climate change to protect young people and nature. See http://pubs.giss.nasa.gov/docs/notyet/submitted_Hansen_etal.pdf. [Google Scholar]49. Rowland D.
2012.
World fish stocks declining faster than feared. Financial Times. See http://www.ft.com/cms/s/2/73d14032-088e-11e2-b37e-00144feabdc0.html#axzz28KxPEqPr.50. Lemonick MD.
2012.
Ocean acidification threatens food security, report. Climate Central. See http://www.climatecentral.org/news/ocean-acidification-threatens-food-security-in-developing-world-study-finds-1503651. Solomon S, Plattner G-K, Knutti R, Friedlingstein P.
2009.
Irreversible climate change due to carbon dioxide emissions. Proc. Natl Acad. Sci. USA
106, 1704–170910.1073/pnas.0812721106 (doi:10.1073/pnas.0812721106) [PMC free article] [PubMed] [CrossRef] [Google Scholar]52. Md. Golam Mahabub Sarwar
2005.
Impacts of sea level rise on the coastal zone of Bangladesh. See http://static.weadapt.org/placemarks/files/225/golam_sarwar.pdf.53. Seto K, Güneralp B, Hutyra LR.
2012.
Global forecasts of urban expansion to 2030 and direct impacts on biodiversity and carbon pools. Proc. Natl Acad. Sci. USA
109, 16 083–16 08810.1073/pnas.1211658109 (doi:10.1073/pnas.1211658109) [PMC free article] [PubMed] [CrossRef] [Google Scholar]54. Ehrlich PR, Ehrlich AH.
2010.
The culture gap and its needed closures. Int. J. Environ. Stud.
67, 481–49210.1080/00207233.2010.510825 (doi:10.1080/00207233.2010.510825) [CrossRef] [Google Scholar]55. Carson R.
1962.
Silent spring. Boston, MA: Houghton Mifflin [Google Scholar]56. World Bank
2012.
Turn down the heat: why a 4°C warmer world must be avoided. Washington DC: World Bank [Google Scholar]57. Schellnhuber HJ.
2008.
Global warming: stop worrying, start panicking. Proc. Natl Acad. Sci. USA
105, 14 239–14 24010.1073/pnas.0807331105 (doi:10.1073/pnas.0807331105) [PMC free article] [PubMed] [CrossRef] [Google Scholar]58. Anderson K, Bows A.
2011.
Beyond ‘dangerous’ climate change: emission: scenarios for a new world. Phil. Trans. R. Soc. A
369, 20–4410.1098/rsta.2010.0290 (doi:10.1098/rsta.2010.0290) [PubMed] [CrossRef] [Google Scholar]59. Fischetti M.
2011.
2° global warming limit called a ‘prescription for disaster’. Sci. Am. See http://blogs.scientificamerican.com/observations/2011/12/06/two-degree-global-warming-limit-is-called-a-prescription-for-disaster/.60. Reich PB, Hobbie SE.
2012.
Decade-long soil nitrogen constraint on the CO2 fertilization of plant biomass. Nat. Clim. Change.10.1038/nclimate1694 (doi:10.1038/nclimate1694) [CrossRef] [Google Scholar]61. Torn MS, Harte J.
2006.
Missing feedbacks, asymmetric uncertainties, and the underestimation of future warming. Geophys. Res. Lett.
33, L10703.10.1029/2005GL025540 (doi:10.1029/2005GL025540) [CrossRef] [Google Scholar]62. Alexander S.
2012.
Degrowth, expensive oil, and the new economics of energy. Real-world Econ. Rev.
61, 40–51
See http://www.energybulletin.net/stories/2012-08-07/degrowth-expensive-oil-and-new-economics-energy. [Google Scholar]63. Makhijani A.
2007.
Carbon-free and nuclear-free; a roadmap for US energy policy. Takoma Park, MD: IEER Press [Google Scholar]64. Harte J, Harte ME. Cool the earth, save the economy: solving the climate crisis is easy. 2008. See http://cooltheearth.us/ . [Google Scholar]65. Klare M.
2012.
World energy report 2012: the good, the bad, and the really, truly ugly. Truthout. See http://bit.ly/TrCGWA.66. Mann ME.
2009.
Defining dangerous anthropogenic interference. Proc. Natl Acad. Sci. USA
106, 4065–406610.1073/pnas.0901303106 (doi:10.1073/pnas.0901303106) [PMC free article] [PubMed] [CrossRef] [Google Scholar]67. McKibben B.
2012.
Global warming's terrifying new math. Rolling Stone. See http://www.rollingstone.com/politics/news/global-warmings-terrifying-new-math-20120719
1–1168. Proctor RN.
2011.
Golden holocaust: origins of the cigarette catastrophe and the case for abolition. Berkeley, CA: University of California Press [Google Scholar]69. Oreskes N, Conway EM.
2010.
Merchants of doubt: how a handful of scientists obscured the truth on issues from tobacco smoke to global warming. New York, NY: Bloomsbury Press [Google Scholar]70. Klein N.
2011.
Capitalism versus the climate. Nation
293, 11–21 [Google Scholar]71. Eilperin J.
2012.
Climate skeptic group works to reverse renewable energy mandates. Washington Post. See http://wapo.st/UToe9b (accessed 24 November).72. Godfray HCJ, et al.
2010.
Food security: the challenge of feeding 9 billion people. Science
327, 812–81810.1126/science.1185383 (doi:10.1126/science.1185383) [PubMed] [CrossRef] [Google Scholar]73. Foley JA, et al.
2011.
Solutions for a cultivated planet. Nature
478, 332–34210.1038/nature10452 (doi:10.1038/nature10452) [PubMed] [CrossRef] [Google Scholar]74. Foley JA.
2011.
Can we feed the world and sustain the planet? A
five-step global plan could double food production by 2050 while greatly
reducing environmental damage. Sci. Am.
305, 60–6510.1038/scientificamerican1111-60 (doi:10.1038/scientificamerican1111-60) [PubMed] [CrossRef] [Google Scholar]75. Ziska LH, et al.
2012.
Food security and climate change: on the
potential to adapt global crop production by active selection to rising
atmospheric carbon dioxide. Proc. R. Soc. B
279, 4097–410510.1098/rspb.2012.1005 (doi:10.1098/rspb.2012.1005) [PMC free article] [PubMed] [CrossRef] [Google Scholar]76. Friedman L.
2012.
India has big plans for burning coal. Sci. Am. See http://www.scientificamerican.com/article.cfm?id=india-has-big-plans-for-burning-coal (accessed 17 September).77. Colborn T, Dumanoski D, Myers JP.
1996.
Our stolen future. New York, NY: Dutton [Google Scholar]78. Myers P, Hessler W.
2007.
Does ‘the dose make the poison’? extensive results challenge a core assumption in toxicology. Environ. Health News. See http://www.environmentalhealthnews.org/sciencebackground/2007/2007-0415nmdrc.html. [Google Scholar]79. Vandenberg LN, et al.
2012.
Hormones and endocrine-disrupting chemicals: low-dose effects and nonmonotonic dose responses. Endocr. Rev.
33, 378–45510.1210/er.2011-1050 (doi:10.1210/er.2011-1050) [PMC free article] [PubMed] [CrossRef] [Google Scholar]80. Battersby S.
2012.
Cool it. New Sci.
2883, 31–35 [Google Scholar]81. Daily GC, Ehrlich PR.
1996.
Impacts of development and global change on the epidemiological environment. Environ. Dev. Econ.
1, 309–34410.1017/S1355770X00000656 (doi:10.1017/S1355770X00000656) [CrossRef] [Google Scholar]82. Wald P.
2008.
Contagious: cultures, carriers, and the outbreak narrative. Durham, NC: Duke University Press [Google Scholar]83. Pirages DC, DeGeest TM.
2003.
Ecological security: an evolutionary perspective on globalization. Lanham, MD: Rowman & Littlefield [Google Scholar]84. Ehrlich PR.
1991.
Population growth and environmental security. Georgia Rev.
45, 223–232 [Google Scholar]85. Shultz GP, Perry WJ, Kissinger HA, Nunn S.
2011.
Deterrence in the age of nuclear proliferation: the doctrine of mutual assured destruction is obsolete in the post-Cold War era. Wall Street J.
See http://on.wsj.com/FLYQco. [Google Scholar]86. Ehrlich PR, et al.
1983.
Long-term biological consequences of nuclear war. Science
222, 1293–130010.1126/science.6658451 (doi:10.1126/science.6658451) [PubMed] [CrossRef] [Google Scholar]87. Myers N.
1993.
Environmental refugees in a globally warmed world. BioScience
43, 752–76110.2307/1312319 (doi:10.2307/1312319) [CrossRef] [Google Scholar]88. Zelman J.
2011.
50 million environmental refugees by 2020, experts predict. Huff Post Green
See http://www.huffingtonpost.com/2011/02/22/environmental-refugees-50_n_826488.html (accessed 22 February)89. Rowley RJ.
2007.
Risk of rising sea level to population and land area. EOS
88, 105–11610.1029/2007EO090001 (doi:10.1029/2007EO090001) [CrossRef] [Google Scholar]90. Osborne F.
1948.
Our plundered planet. Boston, MA: Little, Brown and Company [Google Scholar]91. Vogt W.
1948.
Road to survival. New York, NY: William Sloan [Google Scholar]92. Brown H.
1954.
The challenge of man‘s future: an inquiry concerning the condition of man during the years that lie ahead. New York, NY: Viking [Google Scholar]93. Borgstrom G.
1965.
The hungry planet. New York, NY: Macmillan [Google Scholar]94. Cloud P.
1968.
Realities of mineral distribution. Texas Q.
11, 103–126 [Google Scholar]95. Georgescu-Rogen N.
1974.
The entropy law and the economic process. Cambridge, MA: Harvard University Press [Google Scholar]96. Myers N.
1979.
The sinking ark. New York, NY: Pergamon Press [Google Scholar]97. Dunlap RE, Catton WR.
1979.
Environmental sociology. Annu. Rev. Sociol.
5, 243–27310.1146/annurev.so.05.080179.001331 (doi:10.1146/annurev.so.05.080179.001331) [CrossRef] [Google Scholar]98. Ehrlich PR, Ehrlich AH.
1981.
Extinction: the causes and consequences of the disappearance of species. New York, NY: Random House [Google Scholar]99. Union of Concerned Scientists
1993.
World scientists’ warning to humanity. Cambridge, MA: Union of Concerned Scientists [Google Scholar]100. National Academy of Sciences USA
1993.
A joint statement by fifty-eight of the world's scientific academies. In Population summit of the world‘s scientific academies. New Delhi, India: National Academy Press [Google Scholar]101. Homer-Dixon T.
1994.
Environmental scarcities and violent conflict: evidence from cases. Int. Security
19, 5–4010.2307/2539147 (doi:10.2307/2539147) [CrossRef] [Google Scholar]102. Lovejoy TE.
1994.
The quantification of biodiversity: an esoteric quest or a vital component of sustainable development?
Phil. Trans. R. Soc. Lond. B
345, 81–8710.1098/rstb.1994.0089 (doi:10.1098/rstb.1994.0089) [PubMed] [CrossRef] [Google Scholar]103. Ehrlich PR.
1968.
The population bomb. New York, NY: Ballantine Books [Google Scholar]104. Boulding KE.
1966.
The economics of the coming spaceship earth. In Environmental quality in a growing economy (ed Jarrett H.), pp. 3–14
Baltimore, MD: Johns Hopkins University Press [Google Scholar]105. Daly HE.
1968.
On economics as a life science. J. Polit. Econ.
76, 392–40610.1086/259412 (doi:10.1086/259412) [CrossRef] [Google Scholar]106. Meadows DH, Meadows DL, Randers J, Behrens WW., III
1972.
The limits to growth. Washington, DC: Universe Books [Google Scholar]107. Daly HE.
1973.
Toward a steady-state economy. San Francisco, CA: W.H. Freeman and Co [Google Scholar]108. Hall CAS, Day JW., Jr
2009.
Revisiting the limits to growth after peak oil. Am. Sci.
97, 230–23710.1511/2009.78.230 (doi:10.1511/2009.78.230) [CrossRef] [Google Scholar]109. Hall CAS, Powers R, Schoenberg W.
2008.
Peak oil, EROI, investments and the economy in an uncertain future. In Biofuels, solar and wind as renewable energy systems (ed Pimentel D.), pp. 109–132
Berlin, Germany: Springer [Google Scholar]110. Kiel K, Matheson V, Golembiewski K.
2010.
Luck or skill? An examination of the Ehrlich–Simon bet. Ecol. Econ.
69, 1365–136710.1016/j.ecolecon.2010.03.007 (doi:10.1016/j.ecolecon.2010.03.007) [CrossRef] [Google Scholar]111. Ehrlich PR, Ehrlich AH.
2009.
The population bomb revisited. Electron. J. Sustainable Dev.
1, 63–71 [Google Scholar]112. Millennium Ecosystem Assessment
2005.
Ecosystems and human well-being: synthesis. Washington, DC: Island Press [Google Scholar]113. Homer-Dixon T.
2006.
The upside of down: catastrophe, creativity, and the renewal of civilization. Washington, DC: Island Press [Google Scholar]114. Rockström J, et al.
2009.
Planetary boundaries: exploring the safe operating space for humanity. Ecol. Soc.
14, 32 [Google Scholar]115. Bradshaw C, Giam X, Sodhi N.
2010.
Evaluating the relative environmental impact of countries. PLoS ONE
5, e10440.10.1371/journal.pone.0010440 (doi:10.1371/journal.pone.0010440) [PMC free article] [PubMed] [CrossRef] [Google Scholar]116. Barnosky AD, et al.
2010.
Has the Earth's sixth mass extinction already arrived?
Nature
471, 51–5710.1038/nature09678 (doi:10.1038/nature09678) [PubMed] [CrossRef] [Google Scholar]117. Burger JR, et al.
2012.
The macroecology of sustainability. PLoS Biol.
10, e1001345.10.1371/journal.pbio.1001345 (doi:10.1371/journal.pbio.1001345) [PMC free article] [PubMed] [CrossRef] [Google Scholar]118. Barnosky AD, et al.
2012.
Approaching a state shift in Earth's biosphere. Nature
486, 52–5810.1038/nature11018 (doi:10.1038/nature11018) [PubMed] [CrossRef] [Google Scholar]119. Gerken J.
2012.
Arctic ice melt, sea level rise may pose imminent threat to island nations, climate scientist says. Huff Post Green. See http://www.huffingtonpost.com/2012/10/05/arctic-ice-melt-sea-level-rise_n_1942666.html?utm_hp_ref=green&ncid=edlinkusaolp00000008.120. Turner A.
2009.
Population priorities: the challenge of continued rapid population growth. Phil. Trans. R. Soc. B
364, 2977–298410.1098/rstb.2009.0183 (doi:10.1098/rstb.2009.0183) [PMC free article] [PubMed] [CrossRef] [Google Scholar]121. Ehrlich PR, Kareiva PM, Daily GC.
2012.
Securing natural capital and expanding equity to rescale civilization. Nature
486, 68–7310.1038/nature11157 (doi:10.1038/nature11157) [PubMed] [CrossRef] [Google Scholar]122. May RM.
2006.
Threats to tomorrow's world. Notes Rec. R. Soc.
60, 109–13010.1098/rsnr.2005.0134 (doi:10.1098/rsnr.2005.0134) [CrossRef] [Google Scholar]123. Kennedy D.
2005.
Twilight for the enlightenment?
Science
308, 165.10.1126/science.1112920 (doi:10.1126/science.1112920) [PubMed] [CrossRef] [Google Scholar]124. Hughes JB, Daily GC, Ehrlich PR.
1997.
Population diversity: its extent and extinction. Science
278, 689–69210.1126/science.278.5338.689 (doi:10.1126/science.278.5338.689) [PubMed] [CrossRef] [Google Scholar]125. Hughes JB, Daily GC, Ehrlich PR.
2000.
The loss of population diversity and why it matters. In Nature and human society (ed Raven PH.), pp. 71–83
Washington, DC: National Academy Press [Google Scholar]126. Blumstein DT, Saylan C.
2011.
The failure of environmental education (and how we can fix it). Berkeley, CA: University of California Press [Google Scholar]127. Ehrlich PR.
2011.
A personal view: environmental education—its content and delivery. J. Environ. Stud. Sci.
1, 6–1310.1007/s13412-011-0006-3 (doi:10.1007/s13412-011-0006-3) [CrossRef] [Google Scholar]128. Levin SA.
2009.
Games, groups, and the global good. London, UK: Springer [Google Scholar]129. Levin S.
1999.
Fragile dominion. Reading, MA: Perseus Books [Google Scholar]130. Liu J, Li S, Ouyang Z, Tam C, Chen X.
2008.
Ecological and socioeconomic effects of China's policies for ecosystem services. Proc. Natl Acad. Sci. USA
105, 9489–949410.1073/pnas.0706905105 (doi:10.1073/pnas.0706905105) [PMC free article] [PubMed] [CrossRef] [Google Scholar]131. Daily GC, Kareiva PM, Polasky S, Ricketts TH, Tallis H.
2011.
Mainstreaming natural capital into decisions. In Natural capital: theory and practice of mapping ecosystem services (eds Kareiva PM, Tallis H, Ricketts TH, Daily GC, Polasky S.), pp. 3–14
Oxford, UK: Oxford University Press [Google Scholar]132. Ehrlich PR.
2000.
Human natures: genes, cultures, and the human prospect. Washington, DC: Island Press [Google Scholar]133. James PT, Leach R, Kalamara E, Shayeghi M.
2001.
Worldwide obesity epidemic. Obes. Res.
9(Suppl. 4), S228–S23310.1038/oby.2001.123 (doi:10.1038/oby.2001.123) [PubMed] [CrossRef] [Google Scholar]134. Jackson T.
2009.
Prosperity without growth: economics for a finite planet. London, UK: Earthscan [Google Scholar]135. Gardner H.
2008.
Multiple intelligences: new horizons in theory and practice. New York, NY: Basic Books [Google Scholar]136. Holdren J.
1991.
Population and the energy problem. Popul. Environ.
12, 231–25510.1007/BF01357916 (doi:10.1007/BF01357916) [CrossRef] [Google Scholar]137. Potts M.
2009.
Where next?
Phil. Trans. R. Soc. B
364, 3115–312410.1098/rstb.2009.0181 (doi:10.1098/rstb.2009.0181) [PMC free article] [PubMed] [CrossRef] [Google Scholar]138. Sedgh G, Hussain R, Bankole A, Singh S.
2007.
Women with an unmet need for contraception in developing countries and their reasons for not using a method. In Occasional report, pp. 1–80
New York, NY: Guttmacher Institute [Google Scholar]139. Singh S, Sedgh G, Hussain R.
2010.
Unintended pregnancy: worldwide levels, trends, and outcomes. Stud. Fam. Plann.
41, 241–25010.1111/j.1728-4465.2010.00250.x (doi:10.1111/j.1728-4465.2010.00250.x) [PubMed] [CrossRef] [Google Scholar]140. O'Neill BC, Liddle B, Jiang L, Smith KR, Pachauri S, Dalton M, Fuchs R.
2012.
Demographic change and carbon dioxide emissions. Lancet
380, 157–16410.1016/S0140-6736(12)60958-1 (doi:10.1016/S0140-6736(12)60958-1) [PubMed] [CrossRef] [Google Scholar]141. Ehrlich PR, Ehrlich AH.
2006.
Enough already. New Sci.
191, 46–5010.1016/S0262-4079(06)60615-5 (doi:10.1016/S0262-4079(06)60615-5) [CrossRef] [Google Scholar]142. Turner A.
2009.
Population ageing: what should we worry about?
Phil. Trans. R. Soc. B
364, 3009–302110.1098/rstb.2009.0185 (doi:10.1098/rstb.2009.0185) [PMC free article] [PubMed] [CrossRef] [Google Scholar]143. Victor PA.
2008.
Managing without growth. Northampton, MA: Edward Elgar [Google Scholar]144. Galbraith JK.
2008.
The predator state: how conservatives abandoned the free market and why liberals should to. New York, NY: Free Press [Google Scholar]145. Ariely D.
2009.
Predictably irrational, revised and expanded edition. New York, NY: Harper Collins [Google Scholar]146. Dasgupta P.
2001.
Human well-being and the natural environment. Oxford, UK: Oxford University Press [Google Scholar]147. Dasgupta P.
2010.
Nature's role in sustaining economic development. Phil. Trans. R. Soc. B
365, 5–1110.1098/rstb.2009.0231 (doi:10.1098/rstb.2009.0231) [PMC free article] [PubMed] [CrossRef] [Google Scholar]148. Arrow K, et al.
2004.
Are we consuming too much?
J. Econ. Perspect.
18, 147–17210.1257/0895330042162377 (doi:10.1257/0895330042162377) [CrossRef] [Google Scholar]149. Barrett S.
2003.
Environment and statecraft: the strategy of environmental treaty-making. New York, NY: Oxford University Press [Google Scholar]150. Barrett S.
2007.
Why cooperate: the incentive to supply global public goods. Oxford, UK: Oxford University Press [Google Scholar]151. Dietz T, Ostrom E, Stern PC.
2003.
The struggle to govern the commons. Science
302, 1902–191210.1126/science.1091015 (doi:10.1126/science.1091015) [PubMed] [CrossRef] [Google Scholar]152. Acemoglu D, Robinson J.
2012.
Why nations fail: the origins of power, prosperity, and poverty. New York, NY: Crown Business [Google Scholar]153. Pirages D, Ehrlich PR.
1972.
If all Chinese had wheels. New York Times (16 March, 1972)154. Klare MT.
2008.
Rising powers, shrinking planet: the new geopolitics of energy. New York, NY: Henry Holt and Company [Google Scholar]155. Watts J.
2010.
When a billion Chinese jump. New York, NY: Scribner [Google Scholar]156. Moghaddam FM.
2012.
The omnicultural imperative. Cult. Psychol.
18, 304–33010.1177/1354067X12446230 (doi:10.1177/1354067X12446230) [CrossRef] [Google Scholar]157. Buchan NR, Grimalda G, Wilson R, Brewer M, Fatase E, Foddy M.
2009.
Globalization and human cooperation. Proc. Natl Acad. Sci. USA
106, 4138–414210.1073/pnas.0809522106 (doi:10.1073/pnas.0809522106) [PMC free article] [PubMed] [CrossRef] [Google Scholar]158. Ehrlich PR, Ehrlich AH.
2005.
One with nineveh: politics, consumption, and the human future, (with new afterword). Washington, DC: Island Press [Google Scholar]159. Meyer M.
2009.
The year that changed the world: the untold story behind the fall of the Berlin Wall. New York, NY: Scribner [Google Scholar]160. Ostrom E.
2009.
A polycentric approach for coping with climate change. World Bank Policy Research Working Paper no. 5095161. Cialdini RB.
2008.
Influence: science and practice. Boston, MA: Allyn & Bacon [Google Scholar]162. Barrett S, Dannenberg A.
2012.
Climate negotiations under scientific uncertainty. Proc. Natl Acad. Sci. USA
109, 17 372–17 37610.1073/pnas.1208417109 (doi:10.1073/pnas.1208417109) [PMC free article] [PubMed] [CrossRef] [Google Scholar]163. Matthews JH, Boltz F.
2012.
The shifting boundaries of sustainability science: are we doomed yet?
PLoS Biol.
10, e1001344.10.1371/journal.pbio.1001344 (doi:10.1371/journal.pbio.1001344) [PMC free article] [PubMed] [CrossRef] [Google Scholar]
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