Synchronous failure: the emerging causal architecture of global crisis


Copyright © 2015 by the author(s). Published here under license by the Resilience Alliance.
Homer-Dixon, T., B. Walker, R. Biggs, A.-S. Crépin, C. Folke, E. F. Lambin, G. D. Peterson, J. Rockström, M. Scheffer, W. Steffen,
and M. Troell. 2015. Synchronous failure: the emerging causal architecture of  global crisis. Ecology and Society 20(3): 6. http://dx.doi.
org/10.5751/ES-07681-200306

Synthesis

Synchronous failure: the emerging causal architecture of global crisis
Thomas Homer-Dixon 1, Brian Walker 2, Reinette Biggs 3,4, Anne-Sophie Crépin 3,5, Carl Folke 3,5, Eric F. Lambin 6,7, Garry D. Peterson 
3, Johan Rockström 3, Marten Scheffer 8, Will Steffen 3,9 and Max Troell 3,5

ABSTRACT. Recent global crises reveal an emerging pattern of  causation that could increasingly characterize the birth and progress
of  future global crises. A conceptual framework identifies this pattern’s deep causes, intermediate processes, and ultimate outcomes.
The framework shows how multiple stresses can interact within a single social-ecological system to cause a shift in that system’s behavior,
how simultaneous shifts of  this kind in several largely discrete social-ecological systems can interact to cause a far larger intersystemic
crisis, and how such a larger crisis can then rapidly propagate across multiple system boundaries to the global scale. Case studies of
the 2008-2009 financial-energy and food-energy crises illustrate the framework. Suggestions are offered for future research to explore
further the framework’s propositions.

Key Words: climate change; conventional oil; financial system; global crisis; grain supply; social-ecological system

INTRODUCTION
It has recently been proposed that identifiable boundaries mark
the safe limits of  human alteration of  planetary biophysical
systems such as nitrogen and carbon cycles (Rockström, et al.
2009a, b, Steffen et al. 2015). By this view, exceeding specific levels
of  key variables in these systems significantly raises the likelihood
of  a regime shift, which would be a sharp, nonlinear jump or
“critical transition” to an alternate state (Scheffer 2009, Barnosky
et al. 2012). Should such a transition occur at an Earth-system
level, it could affect vital social and economic systems and quickly
degrade humanity’s condition. For instance, a critical transition
in Earth’s climate could cause a sudden drop in world food output
that then produces, in the absence of  an adequate response,
chronic subnational violence, state failure, and broad
international conflict.  

However, this is a grossly simplistic account of  how a catastrophic
social-ecological crisis of  global scope might occur. In the real
world, any such crisis will have an intricate causal, spatial, and
temporal structure. For example, rather than a single critical
transition at the planetary scale, smaller crises originating within
particular systems or geographical regions might propagate
across system boundaries, connect together, and then expand into
a global crisis (Lee and Preston 2012).  

We argue that recent global crises, especially several that occurred
simultaneously in 2008-2009, reveal an emerging pattern or
architecture of  causation that will increasingly characterize the
birth and progress of  crises in the future. In a conceptual
framework that consists of  a set of  linked propositions, we identify
the deep causes, intermediate processes, and ultimate outcomes
of  this pattern, which we call “synchronous failure” (Homer-
Dixon 2006, Kent 2011).  

Scholars and commentators have recently begun to highlight how
multiple, simultaneous, and interacting global stresses, such as
demographic pressure, climate change, resource scarcities, and

financial instability, are increasing global systemic risk
(Beddington 2009, OECD 2011, WEF 2012, Helbing 2013,
Pamlin and Armstrong 2015). They often describe the situation
that humanity faces now and in coming decades as a “perfect
storm” of  simultaneous crises (Sample 2009, Ahmed 2011,
Ehrlich and Ehrlich 2013, Morgan 2013). Although evocative,
this phrase implies that the crises align solely by chance. We argue
rather that their simultaneity is a manifestation of  an underlying
causal pattern that is becoming more prevalent, and we elaborate
a conceptual framework that provisionally describes this pattern.  

By providing a diagnosis of  the emerging landscape of  global risk,
we hope to deepen scientific inquiry into humanity’s future
challenges. The integrated framework proposed here shows how
multiple stresses can interact within a single social-ecological
system to cause a shift in the system’s behavior, how simultaneous
shifts of  this kind in several largely discrete social-ecological
systems can interact to cause a far larger intersystemic crisis, and
how such a larger crisis can then rapidly propagate across multiple
system boundaries to the global scale.  

We believe we are describing a fundamentally new situation with
deep ethical as well as practical implications. Crises have, of
course, regularly punctuated human affairs throughout our
species’ history. However, when compared with the emerging
pattern of  crisis we discuss here, past crises, we argue, were
generally less global in scope. Those that became truly global,
such as the Great Depression and World War II, were rare and
thus notable partly because of  their global character. Perhaps
more importantly, past crises appear to have been generally less
intersystemic in their causes and consequences (Biggs et al. 2011).  

Because past crises were less globally extensive and intersystemic,
substantial resources external to the affected societies remained
available for repair of  these societies.[1] Partly as a result, affected
societies could learn, innovate, and then perhaps fundamentally
transform themselves and their institutions in the process of

1Balsillie School of  International Affairs, University of  Waterloo, Canada, 2CSIRO Land and Water, Australia, 3Stockholm Resilience Centre,
Stockholm University, Sweden, 4Centre for Studies in Complexity, Stellenbosch University, South Africa, 5Beijer Institute of  Ecological Economics,
Royal Swedish Academy of  Sciences, Sweden, 6Earth and Life Institute, University of  Louvain, Belgium, 7School of  Earth, Energy & Environmental
Sciences and Woods Institute for the Environment, Stanford University, United States, 8Environmental Sciences, Aquatic Ecology and Water Quality
Management, Wageningen Agricultural University, Netherlands, 9Fenner School of  Environment and Society, Australian National University,
Australia



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rebuilding anew, though sometimes learning was limited and crisis
eventually returned.  

Now, we argue, in an era of  global change often called the
Anthropocene (Crutzen and Stoermer 2000, Crutzen 2002,
Steffen et al. 2007), such second chances are becoming rarer. The
global economy has expanded nearly 20-fold since the 1950s, as
measured by total global GDP, and inputs of  resources from
natural systems and outputs of  waste back into those systems
have increased about 7-fold (Krausmann et al. 2009; J. B. DeLong,
unpublished manuscript, http://holtz.org/Library/Social%20Science/
Economics/Estimating%20World%20GDP%20by%20DeLong/
Estimating%20World%20GDP.htm). Many of  these natural
systems, including forests, fisheries, hydrological cycles, and
atmospheric and terrestrial sinks are consequently under
enormous strain, and some, such as Earth’s climate, are exhibiting
a higher frequency of  extreme behavior (Hansen et al. 2012, IPCC
2012). During the same period, the revolution in information
technologies, the quintupling of  global trade, and the
homogenization of  human institutions, culture, and technologies
have produced a sharp increase in the connectivity and the speed
of  operation of  human social and economic systems (Chase-
Dunn et al. 2000, Young et al. 2006).  

The combined result of  these changes has been the emergence for
the first time in human history of  a single, tightly coupled human
social-ecological system of  planetary scope. Tight coupling means
a major crisis is more likely to implicate most if  not all of  this
system, so affected societies will be less likely to have access to
largely unaffected societies and regions from which they can draw
resources, capital, and knowledge for repair and rebuilding.  

In a world where external reserves of  resources are limited and
second chances are thus increasingly rare, humankind must
develop the ability to proactively navigate away from this new
kind of  crisis—globally extensive and intersystemic—that could
otherwise irreversibly degrade the biophysical and economic basis
for human prosperity. Unfortunately, humanity’s existing global
institutions are ill-equipped to provide for such navigation
(Walker et al. 2009). We conclude, therefore, with
recommendations for further research on both emerging patterns
of  global crisis and on pathways for rapid institutional evolution
that could substantially reduce the risk of  synchronous failure.

CONCEPTUAL FRAMEWORK
In this section, we provide definitions of  the core concepts and
identify the main components of  a conceptual framework that
describes synchronous failure. A complex systems ontology
informs this framework (for a survey, see Mitchell 2009).

Definitions
We define a “system” as a set of  causally connected entities that
can be considered as a whole and has sufficiently strong
homeostatic mechanisms to persist as an identifiable whole over
an extended period of  time. The entities making up human social-
ecological systems include resources, nonhuman organisms,
people (including their cognitive states), organizations,
institutions, and technologies (Beddoe et al. 2009).  

A social-ecological system’s “coping capacity” is its ability to
remain within its current stability domain or otherwise shift
noncatastrophically to an alternative stability domain in which

the system’s essential features and functions are sustained. Our
concept of  coping capacity echoes that of  “resilience” (Folke et
al. 2010, Anderies et al. 2013). Our use of  coping capacity,
however, is intended to emphasize actors’ agency, specifically, the
capacity of  individuals or groups to choose how, when, and where
to respond to systemic stress.  

A “stress” is a force that, if  unopposed, will move a system away
from its current state. A “crisis,” in the context of  this paper, is a
sudden event or a closely connected series of  events within or
across social-ecological systems that significantly harms, in a
relatively short period of  time, the well-being of  a large number
of  people.  

This definition of  crisis is substrate-neutral, in the sense that a
crisis so-defined can occur in an ecological, economic, political,
or technological system, or some combination of  the foregoing.
The definition thus allows researchers to subsume under a single
analysis types of  events that are conventionally treated separately.  

The proposed definition stipulates three necessary conditions for
crisis that, taken together, are sufficient for its occurrence:
suddenness (sharp nonlinearity), impact on a large population,
and significant harm to that population within a relatively short
period of  time. Each of  these conditions or properties can be
operationalized.  

In our stipulation that a crisis must actually cause significant
harm, we depart from the conventional usage in which an event
that could potentially lead to significant harm is sometimes called
a crisis. Such usage is common in discussions of  international
affairs, as in the label “Cuban Missile Crisis.” By defining crisis
as a phenomenon that actually causes harm, we make its
identification and measurement less dependent on assessment of
people’s subjective psychological states of, for instance, fear,
anxiety, and perception of  threat.  

The definition also assumes that the harm in question is a direct
result of  the crisis and therefore occurs relatively rapidly. It thus
does not preclude the possibility that a crisis can precipitate widely
beneficial changes in psychological states, social structures, and
general well-being over a longer period of  time.  

Finally, we do not stipulate that unexpectedness, or perceived low
probability, is a necessary condition for crisis, as do some widely
cited definitions.[2] First, events generally understood as crises are
often broadly anticipated. If  Israel attacks Iran to destroy its
nuclear facilities in 2016, the event and its immediate
consequences will be called a crisis, even though they have been
anticipated for years. Second, nearly all crises are anticipated by
someone, even if  only by chance or luck. Therefore,
unexpectedness is not a binary variable, that is, it is not true that
sudden harmful events are either expected or unexpected. Because
unexpectedness is a continuous variable, stipulating it as a
necessary condition would require stipulating what proportion of
the population the crisis must truly surprise, a significant and
unnecessary complication.  

Researchers could use our definition to generate a list of  crises
across recent history, say, the last century. They could then
examine the list to establish trends regarding crisis frequency, type,
and severity and to determine whether new patterns of  crisis are
emerging.



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Deep causes of synchronous failure
We argue that compared to past crises, future crises will
increasingly arise from the conjunction of  three underlying, long-
term, and causally linked global trends. The first is the dramatic
increase in the scale of  human economic activity in relation to
Earth’s natural resources and systems. Human-induced changes
in natural systems now often rival or exceed changes arising from
nonhuman processes (Steffen et al. 2007). The second trend is the
rapidly rising density, capacity, and transmission speed of  the
connections carrying material, energy, and information among
the components of  human technological, economic, and social
systems (Helbing 2013). This increased connectivity reduces the
isolation of  these systems’ components from each other and
thereby increases the functional size of  the overall systems of
which they are a part. The third trend is the increasing
homogeneity, or declining diversity, of  human cultures,
institutions, practices, and technologies (Boli and Thomas 1997,
Meyer 2000, Young et al. 2006), including technologies that
exploit ecosystem services, such as agriculture and aquaculture.
Although market competition in the global economy can promote
diversity, positive network externalities, winner-take-all
dynamics, and efforts by firms to achieve efficiencies and
economies of  scale across enormous markets encourage process
homogeneity and a concomitant pruning of  redundancy and
system slack (Levitt 1983, Arthur 1994, Frank and Cook 1996).  

The second and third of  these trends are reciprocally related, that
is, they are both causes and consequences of  each other, although
not exclusively so. Greater connectivity facilitates homogenization,
while homogenization encourages greater connectivity.  

The three global trends contribute both separately and in
combination to conditions favoring synchronous failure in three
major ways. First, they generate multiple simultaneous stresses
affecting human societies. These stresses build their force slowly
yet are potentially very powerful over time. For instance, the first
of  the three above trends, the sharply rising scale of  human
economic activity in relation to natural resources and systems, is
causing greater scarcity of  some critical resources such as
conventional oil (Sorrell et al. 2012, IEA 2013, Höök et al. 2014),
where this scarcity is gauged by the amount of  energy needed to
extract and process an additional increment of  final output
(Davidson et al. 2014). It is also contributing to higher
atmospheric concentrations of  greenhouse gases, which are
boosting the incidence of  extreme climate events such as heat
waves (Hansen et al. 2012, IPCC 2012). Additionally, it is
producing severe disruption of  many natural systems that are vital
to human well-being, including the majority of  Earth’s fisheries
and large tracts of  its grasslands and forests. For some of  these
systems, such as coral reefs, disruption is approaching or even
exceeding the systems’ homeostatic capacity to maintain their
integrity and identity (Bellwood et al. 2004, Hughes et al. 2010).  

Combinations of  the three global trends can also produce stress.
For example, climate change and the rising energetic cost of  oil,
both a result of  the first trend, are encouraging a transition from
energetically dense carbon-based fuels to alternative energy
sources that are, on average, energetically costlier and less dense
(Heinberg 2009). However, enabling and sustaining the second
trend, the rising connectivity and in turn complexity of  human
societies, requires ever-larger inputs of  high-quality energy
(Odum 1988, Tainter et al. 2003). The fundamental contradiction

between the two trends could cause enormous economic and
social disruption this century (Morgan 2013).  

Second, the three global trends contribute to conditions favoring
synchronous failure by increasing the risk of  large and abrupt
systemic disruption and by helping such disruptions propagate
farther and faster through global networks. For instance, the
increasing density, capacity, and transmission speed of
connections among system components creates tight coupling
among these components, which raises the risk of  surprising and
harmful interactions among them (Perrow 1999) and of  localized
failures spreading quickly to other, distant system components
(Buldyrev et al. 2010, Harmon et al. 2010, Bashan et al. 2013,
Helbing 2013). Research on ecological and other complex
networks suggests that the combination of  rising connectivity and
homogeneity makes a system less adaptive and, ultimately, more
vulnerable to a critical transition, that is, to a wholesale systemic
shift or crash (Bodin and Norberg 2005, Scheffer et al. 2012, Lever
et al 2014).  

However, the same features can also produce benefits. For
instance, greater connectivity can aid repair of  local failures by
facilitating the flow of  inputs from nearby components (Biggs et
al. 2012, Scheffer et al. 2012). Also, the combination of  greater
connectivity and homogeneity in human social systems could set
the stage for beneficial critical transitions, such as a planetary
shift toward more environmentally sustainable values,
institutions, and economic practices.  

The above development, an increased propensity to large
disruptions that propagate farther and faster through global
networks, may be evidence of  a more generalized trend of  direct
relevance to our argument here: greater synchronization in global
systems. Complex systems often exhibit synchronization
(Strogatz 2003). This is an “emergent” phenomenon, that is, a
novel property of  a whole system that arises from the interactions
of  its component parts. Although the underlying causes of
synchronization are still not fully understood, it appears likely to
arise when a dense network of  links among largely homogenous
system components carries signals that create positive feedbacks
among these components. The three global trends identified above
cause today’s global systems to increasingly manifest exactly the
features of  dense connectivity, long-distance teleconnections, and
component homogeneity that seem to encourage synchronization
(Biggs et al. 2011). We will highlight the apparent role of  the global
energy system in synchronizing societal crisis.  

Finally, the three global trends can contribute to conditions
favoring synchronous failure by reducing the coping capacity of
societies. Greater connectivity within and among technological
systems and their associated social systems often makes these
systems’ internal structures and mechanisms more opaque to
system managers, boosts the cognitive and decision-making load
borne by those managers (Barrett et al. 2004, HIMSS 2009), and
generally makes system prediction and control harder.
Opaqueness, managerial overload, and low control are
increasingly apparent in systems as diverse as electrical grids and
the global financial and supply-chain networks (Korowicz 2012,
Lee and Preston 2012, Tollefson 2013).

Processes of synchronous failure
The deep causes we identify above manifest themselves in three
crisis processes that, together, are core characteristics of



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synchronous failure. Each of  these processes usually operates in
conjunction with at least one of  the other two; that is, each is
rarely seen in isolation. However, each is archetypal and as such,
we believe, deserves a distinct label.

Long fuse big bang
The first process, which we call “long fuse big bang” (or LFBB),
arises from the slow accumulation of  a stress or stresses in a social-
ecological system (the burning of  the long fuse) that ultimately
produces a rapid and sharply nonlinear shift in the system’s
behavior (the big bang), perhaps to a new system configuration.
The shift occurs when the level of  stress exceeds the system’s
coping capacity. In other words, it occurs when the ratio of  stress
to the system’s coping capacity exceeds one, assuming that valid,
reliable, and independent instruments to measure both stress and
coping capacity are available. We call this situation “overload.”  

Our conceptualization of  the LFBB archetype derives from two
distinct yet complementary sources: political science theory on
societal crisis and complex systems theory on nonlinear change.
Political scientists Karl Deutsch (1954), Samuel Huntington
(1968), and Alexander Motyl (2001), among others, have
proposed overload-breakdown theories of  social and political
crisis. Huntington, for instance, argues that societies are
vulnerable to instability when their level of  political participation
exceeds their level of  political institutionalization. Such theories,
in turn, trace their origin to at least three distinct lines of  previous
thought (Homer-Dixon 2006): the functionalist sociology of
Émile Durkheim (1951) and Talcott Parsons (1951), the systems
theory and cybernetics pioneered by Ludwig von Bertalanffy
(1950) and Norbert Wiener (1961), and the information-
processing and computational theories of  cognitive scientists and
organizational theorists such as Herbert Simon (1983).  

The other source of  our conceptualization of  LFBB, complex
systems theory, proposes that sharp nonlinear shifts in system
behaviour can arise in two distinct ways. In the first, change in
the values of  one or more state variables causes the system to
jump suddenly from one place to another in a multidimensional
state space; this system “flip” or critical transition can be modeled
as a bifurcation on a catastrophe manifold (Scheffer 2009). In the
second type, potential energy that has slowly accumulated within
the system is released in an “avalanche” event. In systems that
exhibit self-organized criticality, a power law describes the
frequency distribution of  avalanche size (Bak 1996). Very large
events, that is, avalanches in the tail of  the distribution, are
possible.

Simultaneous stresses
The second process of  synchronous failure, which we call the
“simultaneous stresses” (SS), arises when two or more stresses
combine within a single social-ecological system. Correctly
describing the relationship among these multiple stresses is
important, and here two key questions arise. First, are the stresses
causally linked or causally independent? Second, do the stresses,
in their combined effect, have a multiplicative or additive
relationship?  

In regard to the first question, stresses developing within the
tightly coupled social-ecological systems that increasingly
characterize today’s world will rarely if  ever be fully causally
independent of  each other. However, the causal relations between
them can take a variety of  forms, from linear unidirectional

causation at one extreme to highly nonlinear reciprocal (or
feedback) causation at the other extreme. Also, causal links
between stresses can occur along the full range of  temporal stages
in the stresses’ development. Any adequate account of  multiple
stresses must provide detail on such complexities.  

In regard to the second question, a multiplicative relationship
among stresses implies that their combined effect, i.e., total stress,
is not a straight-forward sum of  their individual contributions to
that effect; the relationship among the stresses is therefore
synergistic. Also, a multiplicative relationship among stresses
implies a logical “and” relationship among them, which means
each stress is posited as necessary for the result to occur. In other
words, overload can happen only when stresses X and Y occur
together in sufficient combined strength to exceed the system’s
coping capacity. The outbreak of  a vector-borne disease in a
population, for example, requires both a pathogen and a vector.
Each is necessary for the outbreak to occur, so neither can cause
the outbreak by itself. An additive relationship, on the other hand,
implies a logical “or” relationship, which means any one of  the
identified stresses by itself  could be sufficient for the outcome. In
this case, overload happens when X and/or Y occurs in sufficient
strength to exceed the system’ coping capacity (Mahoney 2008,
Mahoney et al. 2009).[3]  

The actual relationship between stresses in a given situation must
be determined through empirical investigation. It is quite possible,
indeed, that the best representation will involve a combination of
the two types of  relationships. For instance, overload may be
found to happen when (X or Y) and Z occur together. Also,
researchers may determine that the overload outcome is
“equifinal,” which means it could arise along multiple discrete
causal pathways. In this case, researchers should ideally stipulate
each pathway’s sufficient set of  causes.[4] The product of  the
exercise will resemble the kind of  fault-tree model common in risk
analysis (Lee et al. 1985).

Ramifying cascade
The third process archetype, which we call the “ramifying cascade
„ (RC), arises when a sudden and severe perturbation of  one node
in a tightly coupled network propagates through the network’s
links to adjacent nodes, thereby producing knock-on effects at
some distance from the original perturbation. We argued above
that steadily greater connectivity within human technological,
economic, and social networks and between these human
networks and natural systems has increased the frequency and
severity of  unexpected system interactions and of  long-range
cascading system failures (Adger et al. 2009, Galaz et al. 2011,
Korowicz 2012).  

Each of  our process archetypes highlights a distinct and critical
property of  the emerging pattern of  social-ecological crises we
call synchronous failure. The LFBB archetype emphasizes how a
stress on a system can cause a sudden nonlinearity, in which the
rate of  system change shifts abruptly from slow to fast. The SS
archetype highlights how multiple stresses operating
simultaneously can combine in their total impact, often
synergistically. Finally, the RC archetype highlights how
disruptions or shocks arising from sudden nonlinearities can
propagate rapidly through modern tightly coupled social-
ecological networks.



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Fig. 1. Synchronous failure: a conceptual framework showing the emerging causal architecture of
global crisis. SS = simultaneous stresses; LFBB = long fuse big bang; RC = ramifying cascade.

Outcomes of synchronous failure
We argue that the above causes and processes are increasingly
producing crises with a distinct character compared to past crises.
Specifically, synchronous failure, as we call this emerging type of
crisis, is more biophysical in origin, more intersystemic in
manifestation, more global in scope, and more rapid in
development. Together, these four properties increase the risk that
future crises will involve irreversible system flips on human
timescales that have enormous repercussions for humankind.  

In Figure 1, we bring together the various elements of  our
conceptual framework. The figure distinguishes between two
temporal stages. In stage 1, which integrates the SS and LFBB
process archetypes, slow processes operate within largely discrete
systems. Multiple slowly developing stresses combine to cause
overload in these systems. With the "X" symbols between the
converging arrows, we specify that the relationships between the
stresses in each system are multiplicative; as discussed above,
however, these relationships could also be additive.  

The operation of  proximate triggers marks the transition between
stage 1 and stage 2; these triggers cause the overload in each system
to generate discrete systemic crises. The simultaneity or near-
simultaneity of  these crises, that is, the synchronization of  their
crisis behavior, arises from the systems’ causal interaction across
their intersystemic boundary.  

In stage 2, which integrates the SS and RC archetypes, fast
processes operate across multiple systems. Here the simultaneous
but previously largely discrete systemic crises combine, again

synergistically, to produce a single multisystemic crisis that
cascades outward through a tightly coupled global network.  

The SS process archetype appears in both stages. In the stage 1,
it is slow-acting stresses that are multiple; whereas in stage 2, it is
fast-acting crises that are multiple. The RC archetype by definition
involves fast processes, whereas LFBB involves both slow and fast
processes—at first slow and then fast. Our framework implies that
the transition between slow and fast system behavior that
produces a crisis requires something like a LFBB process. The
specific causal mechanisms that produce this nonlinear response
will differ from system to system.  

Some might object that the conceptual framework offered here is
both too deterministic and too pessimistic. In the past, these
critics might argue, multiple stresses and even crises have often
spurred innovation, reorganization, and adaptation rather than
catastrophic system failure. Now humanity’s situation offers even
more reason for optimism: scientific and technological progress
has combined with the globalization of  ideas and communication
systems to greatly boost humankind’s ability to anticipate,
understand, avoid, and respond constructively to crises. Our
framework thus underestimates human societies’ longer term
coping or adaptive capacity. Short-term overload and crisis will
lead in time to creativity and adaptation that leave societies better
off  than they were before (Wilkinson 1973, Simon 1998).  

We acknowledge this objection but argue in response that
humanity’s predicament this century is largely novel and is best
characterized as a race between the rapidly increasing severity
and complexity of  its problems and its improving but nonetheless



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Fig. 2. The 2008 financial-energy crisis. SS = simultaneous stresses; LFBB = long fuse big bang;
RC = ramifying cascade; EROI = energy return on investment.

uncertain ability to anticipate, proactively solve, and
constructively respond to these problems (Homer-Dixon 2000).
In 2015, we cannot be sure of  this race’s outcome. Undoubtedly,
crisis can create opportunities for innovation. However, human
history offers abundant evidence that these opportunities are
often not exploited or that, if  they are, the resulting innovation is
either insufficient or of  the wrong kind to produce a long-term
sustainable outcome (Homer-Dixon 2000). Also, many of  the
most severe problems that humankind now faces, such as climate
change, biodiversity loss, and nutrient pollution involve the
provision of  global public goods (Kaul et al. 2003, Barrett 2007).
Because property rights for these goods are nonexistent, unclear,
or shared, the market institutions that have become the primary
mechanisms of  human innovation often cannot generate an
adequate response (Cornes and Sandler 1996).  

Humanity will respond more effectively to its evolving challenges
if  it better understands these challenges. We propose our
conceptual framework with this goal in mind. It consists of  a
series of  interlinked propositions about the emerging properties
of  global crisis that, we believe, deserve extended close
examination.

ILLUSTRATIONS

Illustration 1: the 2008 financial-energy crisis
All of  our framework’s components are visible in the crisis that
erupted in financial markets and the global economy in 2008.
Most people recall that ongoing troubles in the U.S. subprime
housing market metastasized into a global financial crisis,

precipitated, especially, by the late-September collapse of  the
investment bank Lehman Brothers. However, another event of
global scope occurred that year too: a rapid run-up and then
collapse in oil prices. The price of  light crude oil rose from US$90
to nearly $150 dollars a barrel between January and June and then
plummeted to less than $50 by the end of  the year.  

Although it may seem that the financial crisis and the energy-price
shock were causally independent phenomena, we argue the two
events were connected in their deep causes, proximate triggers,
and intertwined consequences, as illustrated in Figure 2. We
therefore label the event a “financial-energy” crisis. It exhibited
all four properties that we believe will increasingly distinguish
future crises: it was global in scope; it developed extraordinarily
rapidly; it was clearly intersystemic, because it emerged from the
interaction of  humanity’s financial and energy systems; and it was
profoundly biophysical, because it was rooted, in significant part,
in humanity’s use of  natural resources.  

The global energy system is represented at the bottom of  the
figure. Between the mid-1990s and 2008, several slowly building
stresses combined synergistically within that part of  the system
involving liquid transportation fuels. Global demand for liquid
fuels increased one to two percent a year, driven especially by the
giant economies of  China and India as they continued energy-
intensive development and expanded their transportation fleets.
At the same time, a rising proportion of  the planet’s conventional
oil production came from fields that had passed peak output and
were exhibiting year-over-year production declines (Sorrell et al.
2012, IEA 2013, Höök et al. 2014). Finally, the energetic cost of



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finding and producing new sources of  oil continued to rise
steadily, which meant that the energy return on investment (EROI)
fell for both conventional and nonconventional sources (Guilford
et al. 2011, Fournier et al. 2013, Murphy 2014, Hall et al. 2014).[5] 
These stresses combined to sharply reduce slack in the global oil
market, making it more tightly coupled and reducing the elasticity
of  supply for liquids (Murray and King 2012).  

The global financial system is represented on the top of  the figure.
In United States in the 1980s, economic policy makers broke with
the prevailing Keynesian orthodoxy and adopted monetarism,
largely in response to the country’s experience with stagflation
during the previous decade. Federal Reserve Chairman Paul
Volcker used sharply contractionist interest-rate policies to bring
inflation under control. Once inflation subsided, economic policy
makers around the world responded to chronically insufficient
demand, and the labor and capital unemployment it produced,
by encouraging growth in the supply of  credit in the economies
under their direction. An antiregulation economic ideology,
which complemented the monetarist shift, took hold in key policy
circles, especially in the United States.  

The result was a two-decades-long torrent of  liquidity into the
global economy that produced rapid economic growth, especially
in Asia (Reinhart 2012). However, the flood of  liquidity also
helped produce a succession of  speculative bubbles, in East Asia
in the 1990s, in the American information technology sector in
the late 1990s and early 2000s, in the housing sectors in the U.S.
and some parts of  Europe in the late 2000s (Justiniano et al. 2015),
and in natural resource markets in the late 2000s.  

In this context, a number of  economic stresses combined
synergistically during the decade prior to 2008. Easy credit and
deregulation encouraged the practice of  securitizing debt and risk,
which spread across all sectors of  advanced economies and
widened the gap between creditors and the underlying assets
securing their credit. This widening gap, in turn, eroded the ability
of, and the incentive for, creditors and investors to judge asset risk
accurately. Meanwhile, equity traders used increasingly
sophisticated computational and mathematical technologies to
generate securitized assets and estimate their risk, along with
faster communication technologies to trade these assets globally.
The rising complexity of  these assets and the increased density
and speed of  global interconnections between investors,
investments, and markets made the behavior of  the overall
economic system progressively more opaque. Finally, changes in
the architecture of  the global financial network tightened its
coupling and reduced modularity, increased the concentration of
assets and network connections in a small number of  immense
financial institutions, and depressed the diversity of  liabilities and
assets on banks’ balance sheets (Haldane and May 2011, Forbes
2012).  

As a result of  these trends in combination, policymakers,
regulators, economic commentators, and investors increasingly
underestimated systemic risk, that is, risk at the level of  the global
economy as a whole. The prevailing antiregulation ideology gave
key rating agencies such as Standard & Poor’s and Moody’s
latitude to assign triple-A ratings to what were in reality extremely
low-quality assets.  

The left side of  Figure 2 represents the SS and LFBB properties
of  both the energy and financial systems. These systems were

distinct, but they were not fully isolated from each other. Indeed,
even before the stresses identified above were severe inside both
systems, links of  two kinds had developed across their shared
boundary.  

First, there were causal connections from the economic system to
the energy system. The liquidity-driven economic growth from
the late 1980s to the mid-2000s led directly to surging energy and
especially oil consumption. By 2008, speculators with access to
cheap credit and advanced trading technologies were multiplying
the impact of  the underlying absence of  slack in the global oil
market (Juvenal and Petrella 2012).  

Second, there were connections in the reverse direction-from the
energy system to the economic system. From the 1986 to the early
2000s, the energy available in oil was inexpensive by historical
standards. It was cheaper, in real terms, than during the entire
period from 1973 to 1986. Inexpensive energy along with technical
advances such as containerization meant inexpensive
transportation, and inexpensive transportation encouraged the
development of  globe-spanning networks of  producers and
suppliers. The result was a rapid increase in the material
connectivity of  the global economy that paralleled the soaring
information connectivity arising from new information
technologies (Chase-Dunn et al. 2000).  

These bidirectional interactions, we propose, helped synchronize
the behavior of  global economic and energy systems, so that by
mid-2008 both simultaneously reached critical junctures and
exhibited extreme susceptibility to crisis. Within each system,
accumulating stresses had overloaded normal coping
mechanisms, in particular the usual regulating and stabilizing
effects of  markets.  

For instance, in the financial system, U.S. banks could not write
off  fast enough the rapid accumulation of  nonperforming
securitized debt tied to subprime mortgages. Simultaneously, in
the global energy system in the first half  of  2008, rising oil prices
encouraged heavy speculation in oil futures, driving prices even
higher. This was a positive or self-reinforcing feedback. Normally,
price signals in oil markets stimulate negative-feedback behavior:
higher prices bring to market greater oil supply just as they reduce
demand by encouraging conservation; both outcomes, in turn,
lower prices.  

Researchers have not reached a consensus as to the proximate
trigger of  the ensuing global crisis. However, the second stage of
this episode of  synchronous failure may have begun in the vast
suburban and exurban tracts of  housing in California, Nevada,
Arizona, and Florida that were the prime sites of  the mid-2000s
U.S. real-estate bubble. Development of  these tracts made
commercial sense only when gasoline was cheap: many residents
had precarious finances at the best of  times and nearly all had
long commutes to work, often two hours or more. As the U.S.
price of  gasoline passed the psychologically critical threshold of
$4 a gallon, as it did in early June of  2008, a sharply higher fraction
of  residents and of  potential buyers found houses in these zones
unaffordable. Defaults on mortgages on the houses soared, which
meant that the value of  securities backed by the mortgages
plummeted.[6]  

The months of  June through September of  2008 thus saw the
energy and financial crises, until then largely discrete, combine to
spark a global, multisystemic crisis. Markets did not expect



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Fig. 3. The 2008 food-energy crisis. SS = simultaneous stresses; LFBB = long fuse big bang; RC =
ramifying cascade.

Lehman Brothers’ late-September collapse, and they interpreted
the event as indicating the U.S. Federal Reserve could not manage
the rising tide of  defaults (Swedberg 2010). Securitized assets on
the balance sheets of  banks and corporations around the world
suddenly had unknown value. The interdependence of  bank,
hedge fund, and corporate balance sheets tightened the coupling
of  global financial markets, so uncertainty propagated rapidly
through global markets. Banks and firms, not confident of  the
financial viability of  counterparties whose balance sheets they
could no longer evaluate, simply stopped doing business with each
other. Global trade collapsed (Levchenko et al. 2009), and every
major economic region in the world began to contract
simultaneously. Falling demand drove oil prices down nearly one
hundred dollars a barrel in three months.  

Only history’s largest coordinated central-bank intervention,
involving the injection of  trillions of  dollars of  additional
liquidity and outright nationalization of  hundreds of  failing
banks and industries, halted the crisis in late 2008 and early 2009.
However, many of  the underlying stresses that led to the crisis,
including the rising energetic costs of  transportation fuel and the
generally weakly regulation of  financial markets, continue to
operate today.

Illustration 2: the 2008 food-energy crisis
Between 2006 and mid-2008, the average global price of  food
nearly doubled, and in the first half  of  2008 the price of  grain in
particular shot upwards. Because poor people usually spend a

large portion of  household income on food, these sharply higher
prices hurt tens of  millions of  people around the world, causing
a temporary surge in malnutrition in poor countries and
widespread decline in well-being, particularly in urban zones and
among children (Ivanic and Martin 2008, Tiwari and Zaman
2010).  

Researchers generally explain this event as the combined result
of  various weather-related shocks to agricultural trade, the
promotion of  biofuels by rich countries, and the surge in the cost
of  energy inputs to agriculture due to higher oil prices (Headey
and Fan 2008, Headey et al. 2010, Lagi et al. 2011, Wright 2011).
Export bans by a number of  key food-producing countries then
amplified the spike.  

This research rightly emphasizes that many factors interacted to
cause the price surge and that the global energy system played a
central role. However, for the most part it does not distinguish
between long-term stresses and more temporally proximate
causes. Nor, generally, does it explain the mechanisms underlying
the food system’s sharply nonlinear response. Finally, it
insufficiently highlights the crisis’s deeply intersystemic
character.  

We capture these properties in Figure 3, which represents the 2008
food crisis in terms of  our framework. The crisis and more recent
high-amplitude swings in food prices suggest that humanity’s food
system is under extreme pressure and may experience much larger
crises in the future (Berry et al. 2012).  



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Over thousands of  years, humankind extensively transformed
Earth’s biosphere as agriculture gradually expanded and
diversified. In the past century, agriculture’s pace of  change
became much more rapid and its biospheric impacts even more
pronounced. Traditional, diverse agricultural systems of  shifting
cultivation that recycled nutrients through fallow practices or
agroforestry gave way to ecologically far simpler systems relying
heavily on fossil fuels for mechanized labor, irrigation, and inputs
of  fertilizer and pesticide. These new systems originated in Europe
and then spread to the Americas, Asia, and finally parts of  Africa.
They produce cheap food that has enormously improved human
well-being. Nonetheless, because of  poverty, about 1 billion
people remain malnourished today.  

In recent decades, four simultaneous and sometimes
synergistically interacting stresses have been building within this
global food system. The first is steadily diminishing availability
of  new, high-quality agricultural land. Agriculture uses about
35% of  the world’s land. Further expansion is possible, but only
a few countries, such as Angola, Brazil, Congo, Mozambique,
Russia, Zambia, and Tanzania, have enough unused land of
sufficient quality to sustain any substantial increase. There is
substantially less potential additional cropland than is generally
assumed once ecological and socioeconomic constraints and
trade-offs are taken into account (Lambin et al. 2013).  

The second stress is steadily declining marginal returns to
agricultural intensification in many parts of  the world, that is, to
incremental additions of  inputs such as fertilizer, machinery, and
irrigation water (Fuglie 2010). In rich countries, intensification’s
marginal benefits are already low: it can boost agricultural yields,
but sustaining past rates of  output growth through intensification
alone usually produces external costs, such as greater water
pollution and loss of  ecosystem services, and these costs can
significantly offset any benefits (Matson and Vitousek 2006,
Bennett et al. 2014, Rist et al. 2014). In poorer regions where big
gains from intensification are more achievable, social,
infrastructure, and institutional problems often hinder such a
strategy. In the absence of  greater investment in inputs themselves
—use of  more fertilizer and tractors of  the same type, for instance
—better technologies can raise input productivity. A kilogram of
fertilizer will produce much more food if  technology can tell
farmers which parts of  their land need it most. Indeed, in the last
decade, higher input productivity accounted for three-quarters of
growth in the world’s food output (Fuglie 2010, Fuglie et al. 2012),
but productivity improvements appear to be slackening for some
cereals, especially wheat and rice (Ray et al. 2012, Grassini et al.
2013).  

Third, climate change has begun to affect food output by
increasing, in particular, the frequency and severity of  extreme
weather events such as drought (Lobell and Field 2007); this
impact is expected to become much more pronounced in coming
decades, requiring ever-larger investments in new agricultural
technologies and infrastructure (Battisti and Naylor 2009,
Ackerman and Stanton 2013, Dai 2013).  

These first three stresses operate, essentially, on the supply side
of  the global food system. Although they have not halted output
growth (Fuglie et al. 2012), they have constrained this growth and
in some cases offset its economic and social benefits. Meanwhile,
world food demand is rising relentlessly, constituting a fourth

stress. Demand is rising partly because the human population is
still growing by about 70 million people a year and partly because
this population’s steadily higher average income has increased
meat consumption. Greater meat consumption, in turn, drives
overall food consumption up the trophic hierarchy, requiring
greater total food production (Bonhommeau et al. 2013). Higher
demand for food generates opportunity for profit from investment
in agriculture, but the three supply-side stresses described above
can decrease the attractiveness of  such investment. Low
investment further constrains future growth in global food output
and raises the potential for even larger food-price spikes in coming
decades.  

The upper left half  of  Figure 3 represents the global food system,
showing the four above-described simultaneous stresses. Together,
the stresses exhibited SS and LFBB dynamics. In the years prior
to 2007-2008, several of  them, specifically, diminished land
availability, declining marginal returns to intensification, and
rising food demand, started to overload the global food system’s
coping capacity, including its market mechanisms and the
international institutions tasked with responding to food
shortfalls, such as the World Food Program (IDC 2008, WFP
2009). These institutions are supposed to act as stabilizing
(negative) feedbacks in the global food system, but their
effectiveness is doubtful because of  their limited capacity and
operational scope (Walker et al. 2009). The bottom half  of  the
diagram again portrays the global energy system with the three
main stresses as described previously: increasing global demand
for conventional oil, the decline of  mature oil fields, and rising
energetic cost of  finding and producing a marginal barrel of  oil.  

Over the years prior to the 2008 crisis, connections developed in
both directions across the shared boundary between the food and
energy systems, once again contributing, we propose, to their
synchronized crisis behavior. Cheap oil in the 1980s and 1990s
encouraged farmers to increase energy inputs to food production,
through greater mechanization and irrigation and greater use of
fertilizer. Rising oil prices in the 2000s then directly boosted the
cost of  food (Headey and Fan 2008, Baffes and Dennis 2013).
Rising prices also encouraged farmers to use their land to grow
biofuels that substitute for petroleum-derived transportation
fuel.[7] Because cropland can now grow either food or feedstock
for biofuel, human agricultural and energy systems are
bidirectionally coupled (Hertel and Beckman 2011, Searchinger
and Heimlich 2015). Products of  the energy system are an input
to the agricultural system, and products of  the agricultural system
are an input into the energy system.  

Although analysts were aware of  the above factors prior to the
2008 food crisis, the event nevertheless surprised most experts.
Few anticipated how, in the context of  the four stresses on the
food system described here, low carryover stocks of  grain from
2007 amplified the sensitivity of  the global food system to various
proximate shocks, such as an extended Australian drought
(Wright 2011).  

The world’s immediate responses made the problem worse, partly
because the dynamics of  the crisis were so poorly grasped. In
particular, some food-producing countries, including Brazil,
India, and Vietnam, banned exports, further driving up prices
(Mitra and Josling 2009). Also, many countries exhibited little
short-run resilience in the face of  food shortages and price



Ecology and Society 20(3): 6
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increases, having previously reduced their national stores of  grain
on the assumption that efficient international food markets made
large-scale food crises improbable.  

The global financial system played a role too, although it is unclear
how much speculation in futures markets affected the crisis. Some
research shows evidence of  a strong impact, whereas other
research has found little (Gilbert 2010, Lagi et al. 2011, Aulerich
et al. 2013). Nevertheless, it is certainly true that financial
deregulation and the development of  new classes of  derivatives
encouraged index-based investment in food markets that were
previously used almost exclusively to hedge producers’ risk.  

The 2008 food crisis had vast multisystem impacts. We have
mentioned its implications for the well-being of  families,
individuals, and especially children around the world. The surge
in food prices also destabilized many political systems: food riots
and violence broke out in dozens of  poor countries, including
Bangladesh, Burkina Faso, Cameroon, Egypt, Indonesia, and
Yemen. However, the global food system showed resilience over
the medium term. Farmers responded strongly to higher prices:
food production in major wheat and maize exporting countries
rose by 25% to 30% the following year, and China and India
increased their public agricultural spending sharply (Headey et
al. 2010). All the same, prices generally remained higher than they
had been in the 1990s or 2000s, and they appeared to become
more volatile.  

These conditions set the stage for further food-system instability.
In August 2010, Russian authorities banned grain exports after
Russian crops were damaged by severe drought and record heat,
a weather phenomenon possibly attributable to climate change.
Within weeks, key grain prices surged upwards, and in the fourth
quarter of  2010 world food prices overall shot past 2008 levels.
By spring 2011, food prices worldwide were averaging 20% above
2008 levels. Higher food prices were likely a proximate trigger of
the uprisings that began in Tunisia in December 2010 and
convulsed nearly 10 countries in the Middle East and North
Africa through the winter and spring of  2011 (Johnstone and
Mazo 2011, Werrell and Femla 2013).

CONCLUSION: FUTURE RESEARCH
In this paper, we have elaborated a conceptual framework that
shows the emerging causal architecture of  global crisis, which we
call synchronous failure. This framework identifies the
phenomenon’s deep causes, characteristic processes, and common
outcomes. We illustrated our framework with accounts of  two
recent global crises, the 2008 financial-energy crisis and the 2008
food-energy crisis.  

In light of  our analysis, it is striking that both of  these crises
occurred in 2008 and that, in both, the global energy system, in
particular the global conventional-oil system, played a central
role. Indeed, because of  the energy system’s role, both crises could
be considered together as a single three-system instance of
synchronous failure.  

As researchers consider how the form and incidence of  major
crisis is changing, the causal role of  the global energy system
deserves special attention. Only enormous inputs of  inexpensive
high-quality energy can create and sustain the unprecedented
connectivity and complexity of  human civilization, including the
connectivity described here among this civilization’s diverse

component systems. As a provisional hypothesis, therefore, it
seems reasonable to propose that the global energy system helps
to synchronize these systems’ behavior and to stimulate
simultaneous crises within and across them. Other factors such
as global trade and transport systems, the Internet, and
simultaneous scarcity of  multiple resources (Seppelt et al. 2014)
may also play synchronizing roles, but these factors themselves
depend on, and are therefore significantly derivative of, massive
flows of  energy.  

Global adjustment to worsening energy scarcity is unlikely to be
smooth. The rising energetic cost of  energy stimulates boom-bust
investment cycles and alternating episodes of  glut and scarcity
(Jackson and Smith 2014). In late 2014 and early 2015, global oil
supply exceeded demand by a relatively small amount, about 1%
to 2% on a daily basis, yet international oil prices dropped by
50%. The drop has generated instabilities in the global economy,
with key oil-producing economies experiencing a precipitous
decline in revenues. Despite the fall in prices, global oil markets
still exhibit limited slack and therefore remain vulnerable to
geopolitical disruption, arising from, for instance, instability in
the Middle East, that could be the proximate cause of  larger
intersystemic crisis.  

More generally, researchers should closely investigate the
complex, dense, and evolving causal links among humanity’s
energy, food, water, climate, and financial systems, along with the
implications of  these links for long-term human well-being.
Although research programs have explored the relationships
between specific pairs of  these systems, for instance, the water-
food, energy-finance, energy-climate, and climate-food relationships,
no research program has explicated the joint and coevolving
behavior of  all five systems together, especially not in light of  the
biosphere’s capacity to sustain these systems (Steffen et al. 2007,
Galaz et al. 2012). Yet humanity’s fate likely resides at the nexus
of  these systems.[8]  

Our proposed framework could guide a systematic analysis of
recent global crises. Such an analysis would help to refine the
framework. It could also identify early-warning indicators and
appropriate interventions that enhance societal resilience and
adaptive governance and, ultimately, reduce the danger of
synchronous failure.  

__________  
[1] The collapse of  the Soviet Union and its associated empire in
the late 1980s and early 1990s is an example of  such a
geographically and systemically bounded crisis.
[2]For instance, Seeger, Sellnow, and Ulmer define an
organizational crisis as “a specific, unexpected, and nonroutine
event or series of  events that create high levels of  uncertainty and
threaten or are perceived to threaten an organization’s high-
priority goals” (Seeger et al. 1998:233).
[3] In an additive relationship, one stress can mask the effect of
another. For example, high regional concentrations of  sulfate
aerosols can mask the generalized warming effect of  rising
atmospheric concentrations of  carbon dioxide.
[4] Technically, this would be a representation of  INUS causation,
in which each cause is an insufficient but necessary member of  a
set of  causes that is itself  unnecessary but sufficient for the
equifinal outcome of  system overload (Mahoney 2008, Mahoney
et al. 2009).



Ecology and Society 20(3): 6
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[5] The EROI trends mentioned here are well-documented (Hall
et al. 2014). New technologies like hydrofracking and steam-
assisted gravity drainage (SAGD) have brought large quantities
of  new oil online, especially from unconventional tight-oil and
bitumen formations, but this supply is energetically much more
expensive than conventional oil (Murphy 2014). Meanwhile,
around the world mature conventional oil fields are rapidly
declining at about 6% to 7% a year (IEA 2013). Fracking and
SAGD technologies may partially compensate for this decline,
but at greatly increased energetic cost (Hughes 2013).
[6] Hamilton (2009) writes: “[There was] an interaction effect
between the oil shock and the problems in housing. [In] the Los
Angeles, Tampa, Pittsburgh, Chicago, and Portland-Vancouver
Metropolitan Statistical Areas, house prices in 2007 were likely
to rise slightly in the zip codes closest to the central urban areas
but fall significantly in zip codes with longer average commuting
distances. Foreclosure rates also rose with distance from the
center. And certainly to the extent that the oil shock made a direct
contribution to lower income and higher unemployment, that
would also depress housing demand.”
[7] In the United States, this substitution was reinforced by the
2005 Renewable Fuel Standard, which mandates that producers
of  transportation fuel blend into their product a specified
proportion of  biofuels.
[8] The Shell Corporation has sponsored examination of  the links
between the global energy, water, and food systems. See:  http://
s07.static-shell.com/content/dam/shell-new/local/corporate/corporate/
downloads/pdf/powering-progress-together/ppt-rotterdam-2014-
event-report-240614.pdf.

Responses to this article can be read online at: 
http://www.ecologyandsociety.org/issues/responses.
php/7681

Acknowledgments:

We wish to acknowledge the substantive contributions of Nick
Bostrom, Gary Bowden, Lisa Deutsch, Jerker Lokrantz, Eric
Nævdal, Toby Ord, and Anders Sandberg. Reinette Biggs is
supported by a Swiss ETH Society in Science Fellowship, and a
Mistra grant to the Stockholm Resilience Centre. This article was
initiated at the Inconvenient Feedbacks in Global Dynamics
workshop, organized in April 2010 in Stockholm as part of the joint
research program on “Global dynamics and resilience,” of the Beijer
Institute of Ecological Economics of the Royal Swedish Academy
of Sciences and the Stockholm Resilience Centre. Economic support
from the Anna-Greta och Holger Crafoords foundation and the
foundation Till Bröderna Jacob och Marcus Wallenbergs minne is
gratefully acknowledged. Many thanks to Joan Hewer for assisting
with research and formatting and to Jerker Lokrantz for preparing
the figures.

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