Global catastrophic risk

A global catastrophic risk is a hypothetical future event which could damage human well-being on a global scale,[2] even endangering or destroying modern civilization.[3] An event that could cause human extinction or permanently and drastically curtail humanity's potential is known as an existential risk.[4]

Artist's impression of a major asteroid impact. An asteroid with an impact strength of a billion atomic bombs may have caused the extinction of the dinosaurs.[1]

Potential global catastrophic risks include anthropogenic risks, caused by humans (technology, governance, climate change), and non-anthropogenic or external risks.[3] Examples of technology risks are hostile artificial intelligence and destructive biotechnology or nanotechnology. Insufficient or malign global governance creates risks in the social and political domain, such as a global war, including nuclear holocaust, bioterrorism using genetically modified organisms, cyberterrorism destroying critical infrastructure like the electrical grid; or the failure to manage a natural pandemic. Problems and risks in the domain of earth system governance include global warming, environmental degradation, including extinction of species, famine as a result of non-equitable resource distribution, human overpopulation, crop failures and non-sustainable agriculture.

Examples of non-anthropogenic risks are an asteroid impact event, a supervolcanic eruption, a lethal gamma-ray burst, a geomagnetic storm destroying electronic equipment, natural long-term climate change, hostile extraterrestrial life, or the predictable Sun transforming into a red giant star engulfing the Earth.

Classifications

Scope/intensity grid from Bostrom's paper "Existential Risk Prevention as Global Priority"[5]

Global catastrophic vs. existential

A global catastrophic risk is any risk that is at least global in scope, and is not subjectively imperceptible in intensity. Those that will affect all future generations and are "terminal" in intensity are classified as existential risks. While a global catastrophic risk may kill the vast majority of life on earth, humanity could still potentially recover. An existential risk, on the other hand, is one that either destroys humanity entirely or prevents any chance of civilization's recovery. [6]

Similarly, in Catastrophe: Risk and Response, Richard Posner singles out and groups together events that bring about "utter overthrow or ruin" on a global, rather than a "local or regional" scale. Posner singles out such events as worthy of special attention on cost-benefit grounds because they could directly or indirectly jeopardize the survival of the human race as a whole.[7] Posner's events include meteor impacts, runaway global warming, grey goo, bioterrorism, and particle accelerator accidents.

Studying near-human extinction directly is not possible, and modelling existential risks is difficult, due in part to survivorship bias.[8] However, individual civilizations have collapsed many times in human history. While there is no known precedent for a complete collapse into an amnesic pre-agricultural society, civilizations such as the Roman Empire have ended in a loss of centralized governance and a major civilization-wide loss of infrastructure and advanced technology. Societies are often resilient to catastrophe; for example, Medieval Europe survived the Black Death without suffering anything resembling a civilization collapse.[9]

Likelihood

Some risks are due to phenomena that have occurred in Earth's past and left a geological record. Together with contemporary observations, it is possible to make informed estimates of the likelihood such events will occur in the future. For example, an extinction-level comet or asteroid impact event before the year 2100 has been estimated at one-in-a-million.[10][11] Supervolcanoes are another example. There are several known historical supervolcanoes, including Mt. Toba, which some say almost wiped out humanity at the time of its last eruption. The geologic record suggests this particular supervolcano re-erupts about every 50,000 years.[12][13]

Without the benefit of geological records and direct observation, the relative danger posed by other threats is much more difficult to calculate. In addition, it is one thing to estimate the likelihood of an event taking place, but quite another to assess how likely an event is to cause extinction if it does occur, and most difficult of all, the risk posted by synergistic effects of multiple events taking place simultaneously.

The closest the Doomsday Clock has been to midnight is 2020, when the Clock was set to one minute forty seconds until midnight, due to continued relations troubles between the North Korean and United States governments, as well as rising tensions between the US and Iran.[14]

Given the limitations of ordinary calculation and modeling, expert elicitation is frequently used instead to obtain probability estimates.[15] In 2008, an informal survey of experts on different global catastrophic risks at the Global Catastrophic Risk Conference at the University of Oxford suggested a 19% chance of human extinction by the year 2100. The conference report cautions that the results should be taken "with a grain of salt"; the results were not meant to capture all large risks and did not include things like climate change, and the results likely reflect many cognitive biases of the conference participants.[16]

RiskEstimated probability
for human extinction
before 2100
Overall probability
19%
Molecular nanotechnology weapons
5%
Superintelligent AI
5%
All wars (including civil wars)
4%
Engineered pandemic
2%
Nuclear war
1%
Nanotechnology accident
0.5%
Natural pandemic
0.05%
Nuclear terrorism
0.03%
Table source: Future of Humanity Institute, 2008.[17]

The 2016 annual report by the Global Challenges Foundation estimates that an average American is more than five times more likely to die during a human-extinction event than in a car crash.[18][19]

There are significant methodological challenges in estimating these risks with precision. Most attention has been given to risks to human civilization over the next hundred years, but forecasting for this length of time is difficult. The types of threats posed by nature have been argued to be relatively constant, though this has been disputed,[20] and new risks could be discovered. Anthropogenic threats, however, are likely to change dramatically with the development of new technology; while volcanoes have been a threat throughout history, nuclear weapons have been an issue only since the 20th century. Historically, the ability of experts to predict the future over these timescales has proved very limited. Man-made threats such as nuclear war or nanotechnology are harder to predict than natural threats, due to the inherent methodological difficulties in the social sciences. In general, it is hard to estimate the magnitude of the risk from this or other dangers, especially as both international relations and technology can change rapidly.

Existential risks pose unique challenges to prediction, even more than other long-term events, because of observation selection effects. Unlike with most events, the failure of a complete extinction event to occur in the past is not evidence against their likelihood in the future, because every world that has experienced such an extinction event has no observers, so regardless of their frequency, no civilization observes existential risks in its history.[8] These anthropic issues can be avoided by looking at evidence that does not have such selection effects, such as asteroid impact craters on the Moon, or directly evaluating the likely impact of new technology.[5]

In addition to known and tangible risks, unforeseeable black swan extinction events may occur, presenting an additional methodological problem.[21]

Moral importance of existential risk

Some scholars have strongly favored reducing existential risk on the grounds that it greatly benefits future generations. Derek Parfit argues that extinction would be a great loss because our descendants could potentially survive for four billion years before the expansion of the Sun makes the Earth uninhabitable.[22][23] Nick Bostrom argues that there is even greater potential in colonizing space. If future humans colonize space, they may be able to support a very large number of people on other planets, potentially lasting for trillions of years.[6] Therefore, reducing existential risk by even a small amount would have a very significant impact on the expected number of people who will exist in the future.

Exponential discounting might make these future benefits much less significant. However, Jason Matheny has argued that such discounting is inappropriate when assessing the value of existential risk reduction.[10]

Some economists have discussed the importance of global catastrophic risks, though not existential risks. Martin Weitzman argues that most of the expected economic damage from climate change may come from the small chance that warming greatly exceeds the mid-range expectations, resulting in catastrophic damage.[24] Richard Posner has argued that humanity is doing far too little, in general, about small, hard-to-estimate risks of large-scale catastrophes.[25]

Numerous cognitive biases can influence people's judgment of the importance of existential risks, including scope insensitivity, hyperbolic discounting, availability heuristic, the conjunction fallacy, the affect heuristic, and the overconfidence effect.[26]

Scope insensitivity influences how bad people consider the extinction of the human race to be. For example, when people are motivated to donate money to altruistic causes, the quantity they are willing to give does not increase linearly with the magnitude of the issue: people are roughly as concerned about 200,000 birds getting stuck in oil as they are about 2,000.[27] Similarly, people are often more concerned about threats to individuals than to larger groups.[26]

There are economic reasons that can explain why so little effort is going into existential risk reduction. It is a global good, so even if a large nation decreases it, that nation will enjoy only a small fraction of the benefit of doing so. Furthermore, the vast majority of the benefits may be enjoyed by far future generations, and though these quadrillions of future people would in theory perhaps be willing to pay massive sums for existential risk reduction, no mechanism for such a transaction exists.[5]

Potential sources of risk

Some sources of catastrophic risk are natural, such as meteor impacts or supervolcanoes. Some of these have caused mass extinctions in the past. On the other hand, some risks are man-made, such as global warming,[28] environmental degradation, engineered pandemics and nuclear war.[29]

Anthropogenic

The Cambridge Project at Cambridge University says the "greatest threats" to the human species are man-made; they are artificial intelligence, global warming, nuclear war, and rogue biotechnology.[30] The Future of Humanity Institute also states that human extinction is more likely to result from anthropogenic causes than natural causes.[5][31]

Artificial intelligence

It has been suggested that if AI systems rapidly become superintelligent, they may take unforeseen actions or out-compete humanity.[32] According to philosopher Nick Bostrom, it is possible that the first superintelligence to emerge would be able to bring about almost any possible outcome it valued, as well as to foil virtually any attempt to prevent it from achieving its objectives.[33] Thus, even a superintelligence indifferent to humanity could be dangerous if it perceived humans as an obstacle to unrelated goals. In Bostrom's book Superintelligence, he defines this as the control problem.[34] Physicist Stephen Hawking, Microsoft founder Bill Gates, and SpaceX founder Elon Musk have echoed these concerns, with Hawking theorizing that such an AI could "spell the end of the human race".[35]

In 2009, the Association for the Advancement of Artificial Intelligence (AAAI) hosted a conference to discuss whether computers and robots might be able to acquire any sort of autonomy, and how much these abilities might pose a threat or hazard. They noted that some robots have acquired various forms of semi-autonomy, including being able to find power sources on their own and being able to independently choose targets to attack with weapons. They also noted that some computer viruses can evade elimination and have achieved "cockroach intelligence". They noted that self-awareness as depicted in science-fiction is probably unlikely, but there are other potential hazards and pitfalls.[36] Various media sources and scientific groups have noted separate trends in differing areas which might together result in greater robotic functionalities and autonomy, and which pose some inherent concerns.[37][38]

A survey of AI experts estimated that the chance of human-level machine learning having an "extremely bad (e.g., human extinction)" long-term effect on humanity is 5%.[39] A 2008 survey by the Future of Humanity Institute estimated a 5% probability of extinction by superintelligence by 2100.[16] Eliezer Yudkowsky believes risks from artificial intelligence are harder to predict than any other known risks due to bias from anthropomorphism. Since people base their judgments of artificial intelligence on their own experience, he claims they underestimate the potential power of AI.[40]

Biotechnology

Biotechnology can pose a global catastrophic risk in the form of bioengineered organisms (viruses, bacteria, fungi, plants or animals). In many cases the organism will be a pathogen of humans, livestock, crops or other organisms we depend upon (e.g. pollinators or gut bacteria). However, any organism able to catastrophically disrupt ecosystem functions, e.g. highly competitive weeds, outcompeting essential crops, poses a biotechnology risk.

A biotechnology catastrophe may be caused by accidentally releasing a genetically engineered organism from controlled environments, by the planned release of such an organism which then turns out to have unforeseen and catastrophic interactions with essential natural or agro-ecosystems, or by intentional usage of biological agents in biological warfare or bioterrorism attacks.[41] Pathogens may be intentionally or unintentionally genetically modified to change virulence and other characteristics.[41] For example, a group of Australian researchers unintentionally changed characteristics of the mousepox virus while trying to develop a virus to sterilize rodents.[41] The modified virus became highly lethal even in vaccinated and naturally resistant mice.[42][43] The technological means to genetically modify virus characteristics are likely to become more widely available in the future if not properly regulated.[41]

Terrorist applications of biotechnology have historically been infrequent. To what extent this is due to a lack of capabilities or motivation is not resolved.[41] However, given current development, more risk from novel, engineered pathogens is to be expected in the future.[41] Exponential growth has been observed in the biotechnology sector, and Noun and Chyba predict that this will lead to major increases in biotechnological capabilities in the coming decades.[41] They argue that risks from biological warfare and bioterrorism are distinct from nuclear and chemical threats because biological pathogens are easier to mass-produce and their production is hard to control (especially as the technological capabilities are becoming available even to individual users).[41] In 2008, a survey by the Future of Humanity Institute estimated a 2% probability of extinction from engineered pandemics by 2100.[16]

Noun and Chyba propose three categories of measures to reduce risks from biotechnology and natural pandemics: Regulation or prevention of potentially dangerous research, improved recognition of outbreaks and developing facilities to mitigate disease outbreaks (e.g. better and/or more widely distributed vaccines).[41]

Cyberattack

Cyberattacks have the potential to destroy everything from personal data to electric grids. Christine Peterson, co-founder and past president of the Foresight Institute, believes a cyberattack on electric grids has the potential to be a catastrophic risk.[44]

Environmental disaster

An environmental or ecological disaster, such as world crop failure and collapse of ecosystem services, could be induced by the present trends of overpopulation, economic development, and non-sustainable agriculture. Most environmental scenarios involve one or more of the following: Holocene extinction event,[45] scarcity of water that could lead to approximately half the Earth's population being without safe drinking water, pollinator decline, overfishing, massive deforestation, desertification, climate change, or massive water pollution episodes. Detected in the early 21st century, a threat in this direction is colony collapse disorder,[46] a phenomenon that might foreshadow the imminent extinction[47] of the Western honeybee. As the bee plays a vital role in pollination, its extinction would severely disrupt the food chain.

An October 2017 report published in The Lancet stated that toxic air, water, soils, and workplaces were collectively responsible for nine million deaths worldwide in 2015, particularly from air pollution which was linked to deaths by increasing susceptibility to non-infectious diseases, such as heart disease, stroke, and lung cancer.[48] The report warned that the pollution crisis was exceeding "the envelope on the amount of pollution the Earth can carry" and "threatens the continuing survival of human societies".[48]

Experimental technology accident

Nick Bostrom suggested that in the pursuit of knowledge, humanity might inadvertently create a device that could destroy Earth and the Solar System.[49] Investigations in nuclear and high-energy physics could create unusual conditions with catastrophic consequences. For example, scientists worried that the first nuclear test might ignite the atmosphere.[50][51] Others worried that the RHIC[52] or the Large Hadron Collider might start a chain-reaction global disaster involving black holes, strangelets, or false vacuum states. These particular concerns have been refuted,[53][54][55][56] but the general concern remains.

Biotechnology could lead to the creation of a pandemic, chemical warfare could be taken to an extreme, nanotechnology could lead to grey goo in which out-of-control self-replicating robots consume all living matter on earth while building more of themselves—in both cases, either deliberately or by accident.[57]

Global warming

Global warming refers to the warming caused by human technology since the 19th century or earlier. Projections of future climate change suggest further global warming, sea level rise, and an increase in the frequency and severity of some extreme weather events and weather-related disasters. Effects of global warming include loss of biodiversity, stresses to existing food-producing systems, increased spread of known infectious diseases such as malaria, and rapid mutation of microorganisms. In November 2017, a statement by 15,364 scientists from 184 countries indicated that increasing levels of greenhouse gases from use of fossil fuels, human population growth, deforestation, and overuse of land for agricultural production, particularly by farming ruminants for meat consumption, are trending in ways that forecast an increase in human misery over coming decades.[3]

Mineral resource exhaustion

Romanian American economist Nicholas Georgescu-Roegen, a progenitor in economics and the paradigm founder of ecological economics, has argued that the carrying capacity of Earth—that is, Earth's capacity to sustain human populations and consumption levels—is bound to decrease sometime in the future as Earth's finite stock of mineral resources is presently being extracted and put to use; and consequently, that the world economy as a whole is heading towards an inevitable future collapse, leading to the demise of human civilization itself.[58]:303f Ecological economist and steady-state theorist Herman Daly, a student of Georgescu-Roegen, has propounded the same argument by asserting that "... all we can do is to avoid wasting the limited capacity of creation to support present and future life [on Earth]." [59]:370

Ever since Georgescu-Roegen and Daly published these views, various scholars in the field have been discussing the existential impossibility of allocating earth's finite stock of mineral resources evenly among an unknown number of present and future generations. This number of generations is likely to remain unknown to us, as there is no way—or only little way—of knowing in advance if or when mankind will ultimately face extinction. In effect, any conceivable intertemporal allocation of the stock will inevitably end up with universal economic decline at some future point.[60]:253–256 [61]:165 [62]:168–171 [63]:150–153 [64]:106–109 [65]:546–549 [66]:142–145 [67]

Nanotechnology

Many nanoscale technologies are in development or currently in use.[68] The only one that appears to pose a significant global catastrophic risk is molecular manufacturing, a technique that would make it possible to build complex structures at atomic precision.[69] Molecular manufacturing requires significant advances in nanotechnology, but once achieved could produce highly advanced products at low costs and in large quantities in nanofactories of desktop proportions.[68][69] When nanofactories gain the ability to produce other nanofactories, production may only be limited by relatively abundant factors such as input materials, energy and software.[68]

Molecular manufacturing could be used to cheaply produce, among many other products, highly advanced, durable weapons.[68] Being equipped with compact computers and motors these could be increasingly autonomous and have a large range of capabilities.[68]

Chris Phoenix and Treder classify catastrophic risks posed by nanotechnology into three categories:

  1. From augmenting the development of other technologies such as AI and biotechnology.
  2. By enabling mass-production of potentially dangerous products that cause risk dynamics (such as arms races) depending on how they are used.
  3. From uncontrolled self-perpetuating processes with destructive effects.

Several researchers say the bulk of risk from nanotechnology comes from the potential to lead to war, arms races and destructive global government.[42][68][70] Several reasons have been suggested why the availability of nanotech weaponry may with significant likelihood lead to unstable arms races (compared to e.g. nuclear arms races):

  1. A large number of players may be tempted to enter the race since the threshold for doing so is low;[68]
  2. The ability to make weapons with molecular manufacturing will be cheap and easy to hide;[68]
  3. Therefore, lack of insight into the other parties' capabilities can tempt players to arm out of caution or to launch preemptive strikes;[68][71]
  4. Molecular manufacturing may reduce dependency on international trade,[68] a potential peace-promoting factor;
  5. Wars of aggression may pose a smaller economic threat to the aggressor since manufacturing is cheap and humans may not be needed on the battlefield.[68]

Since self-regulation by all state and non-state actors seems hard to achieve,[72] measures to mitigate war-related risks have mainly been proposed in the area of international cooperation.[68][73] International infrastructure may be expanded giving more sovereignty to the international level. This could help coordinate efforts for arms control. International institutions dedicated specifically to nanotechnology (perhaps analogously to the International Atomic Energy Agency IAEA) or general arms control may also be designed.[73] One may also jointly make differential technological progress on defensive technologies, a policy that players should usually favour.[68] The Center for Responsible Nanotechnology also suggests some technical restrictions.[74] Improved transparency regarding technological capabilities may be another important facilitator for arms-control.

Grey goo is another catastrophic scenario, which was proposed by Eric Drexler in his 1986 book Engines of Creation[75] and has been a theme in mainstream media and fiction.[76][77] This scenario involves tiny self-replicating robots that consume the entire biosphere using it as a source of energy and building blocks. Nowadays, however, nanotech experts—including Drexler—discredit the scenario. According to Phoenix, a "so-called grey goo could only be the product of a deliberate and difficult engineering process, not an accident".[78]

Warfare and mass destruction

Joseph Pennell's 1918 Liberty bond poster calls up the pictorial image of an invaded, burning New York City.

The scenarios that have been explored most frequently are nuclear warfare and doomsday devices. Mistakenly launching a nuclear attack in response to a false alarm is one possible scenario; this nearly happened during the 1983 Soviet nuclear false alarm incident. Although the probability of a nuclear war per year is slim, Professor Martin Hellman has described it as inevitable in the long run; unless the probability approaches zero, inevitably there will come a day when civilization's luck runs out.[79] During the Cuban missile crisis, U.S. president John F. Kennedy estimated the odds of nuclear war at "somewhere between one out of three and even".[80] The United States and Russia have a combined arsenal of 14,700 nuclear weapons,[81] and there is an estimated total of 15,700 nuclear weapons in existence worldwide.[81] Beyond nuclear, other military threats to humanity include biological warfare (BW). By contrast, chemical warfare, while able to create multiple local catastrophes, is unlikely to create a global one.

Nuclear war could yield unprecedented human death tolls and habitat destruction. Detonating large numbers of nuclear weapons would have an immediate, short term and long-term effects on the climate, causing cold weather and reduced sunlight and photosynthesis[82] that may generate significant upheaval in advanced civilizations.[83] However, while popular perception sometimes takes nuclear war as "the end of the world", experts assign low probability to human extinction from nuclear war.[84][85] In 1982, Brian Martin estimated that a US–Soviet nuclear exchange might kill 400–450 million directly, mostly in the United States, Europe and Russia, and maybe several hundred million more through follow-up consequences in those same areas.[84] In 2008, a survey by the Future of Humanity Institute estimated a 4% probability of extinction from warfare by 2100, with a 1% chance of extinction from nuclear warfare.[16]

World population and agricultural crisis

M. King Hubbert's prediction of world petroleum production rates. Modern agriculture is heavily dependent on petroleum energy.

The 20th century saw a rapid increase in human population due to medical developments and massive increases in agricultural productivity[86] such as the Green Revolution.[87] Between 1950 and 1984, as the Green Revolution transformed agriculture around the globe, world grain production increased by 250%. The Green Revolution in agriculture helped food production to keep pace with worldwide population growth or actually enabled population growth. The energy for the Green Revolution was provided by fossil fuels in the form of fertilizers (natural gas), pesticides (oil), and hydrocarbon-fueled irrigation.[88] David Pimentel, professor of ecology and agriculture at Cornell University, and Mario Giampietro, senior researcher at the National Research Institute on Food and Nutrition (INRAN), place in their 1994 study Food, Land, Population and the U.S. Economy the maximum U.S. population for a sustainable economy at 200 million. To achieve a sustainable economy and avert disaster, the United States must reduce its population by at least one-third, and world population will have to be reduced by two-thirds, says the study.[89]

The authors of this study believe the mentioned agricultural crisis will begin to have an effect on the world after 2020, and will become critical after 2050. Geologist Dale Allen Pfeiffer claims that coming decades could see spiraling food prices without relief and massive starvation on a global level such as never experienced before.[90][91]

Since supplies of petroleum and natural gas are essential to modern agriculture techniques, a fall in global oil supplies (see peak oil for global concerns) could cause spiking food prices and unprecedented famine in the coming decades.[92][93]

Wheat is humanity's third-most-produced cereal. Extant fungal infections such as Ug99[94] (a kind of stem rust) can cause 100% crop losses in most modern varieties. Little or no treatment is possible and infection spreads on the wind. Should the world's large grain-producing areas become infected, the ensuing crisis in wheat availability would lead to price spikes and shortages in other food products.[95]

Non-anthropogenic

Asteroid impact

Several asteroids have collided with Earth in recent geological history. The Chicxulub asteroid, for example, was about six miles in diameter and is theorized to have caused the extinction of non-avian dinosaurs at the end of the Cretaceous. No sufficiently large asteroid currently exists in an Earth-crossing orbit; however, a comet of sufficient size to cause human extinction could impact the Earth, though the annual probability may be less than 10−8.[96] Geoscientist Brian Toon estimates that while a few people, such as "some fishermen in Costa Rica", could plausibly survive a six-mile meteorite, a sixty-mile meteorite would be large enough to "incinerate everybody".[97] Asteroids with around a 1 km diameter have impacted the Earth on average once every 500,000 years; these are probably too small to pose an extinction risk, but might kill billions of people.[96][98] Larger asteroids are less common. Small near-Earth asteroids are regularly observed and can impact anywhere on the Earth injuring local populations.[99] As of 2013, Spaceguard estimates it has identified 95% of all NEOs over 1 km in size.[100]

In April 2018, the B612 Foundation reported "It's a 100 per cent certain we'll be hit [by a devastating asteroid], but we're not 100 per cent sure when."[101][102] Also in 2018, physicist Stephen Hawking, in his final book Brief Answers to the Big Questions, considered an asteroid collision to be the biggest threat to the planet.[103][104][105] In June 2018, the US National Science and Technology Council warned that America is unprepared for an asteroid impact event, and has developed and released the "National Near-Earth Object Preparedness Strategy Action Plan" to better prepare.[106][107][108][109][110] According to expert testimony in the United States Congress in 2013, NASA would require at least five years of preparation before a mission to intercept an asteroid could be launched.[111]

Cosmic threats

A number of astronomical threats have been identified. Massive objects, e.g. a star, large planet or black hole, could be catastrophic if a close encounter occurred in the Solar System. In April 2008, it was announced that two simulations of long-term planetary movement, one at the Paris Observatory and the other at the University of California, Santa Cruz, indicate a 1% chance that Mercury's orbit could be made unstable by Jupiter's gravitational pull sometime during the lifespan of the Sun. Were this to happen, the simulations suggest a collision with Earth could be one of four possible outcomes (the others being Mercury colliding with the Sun, colliding with Venus, or being ejected from the Solar System altogether). If Mercury were to collide with Earth, all life on Earth could be obliterated entirely: an asteroid 15 km wide is believed to have caused the extinction of the non-avian dinosaurs, whereas Mercury is 4,879 km in diameter.[112]

Conjectured illustration of the scorched Earth after the Sun has entered the red giant phase, about seven billion years from now[113]

If our universe lies within a false vacuum, a bubble of lower-energy vacuum could come to exist by chance or otherwise in our universe, and catalyze the conversion of our universe to a lower energy state in a volume expanding at nearly the speed of light, destroying all that we know without forewarning. Such an occurrence is called vacuum decay.[114][115]

Another cosmic threat is a gamma-ray burst, typically produced by a supernova when a star collapses inward on itself and then "bounces" outward in a massive explosion. Under certain circumstances, these events are thought to produce massive bursts of gamma radiation emanating outward from the axis of rotation of the star. If such an event were to occur oriented towards the Earth, the massive amounts of gamma radiation could significantly affect the Earth's atmosphere and pose an existential threat to all life. Such a gamma-ray burst may have been the cause of the Ordovician–Silurian extinction events. Neither this scenario nor the destabilization of Mercury's orbit are likely in the foreseeable future.[116]

A powerful solar flare or solar superstorm, which is a drastic and unusual decrease or increase in the Sun's power output, could have severe consequences for life on Earth.[117][118]

Astrophysicists currently calculate that in a few billion years the Earth will probably be swallowed by the expansion of the Sun into a red giant star.[119][120]

Extraterrestrial invasion

Intelligent extraterrestrial life, if existent, could invade Earth[121] either to exterminate and supplant human life, enslave it under a colonial system, steal the planet's resources, or destroy the planet altogether.

Although evidence of alien life has never been proven, scientists such as Carl Sagan have postulated that the existence of extraterrestrial life is very likely. In 1969, the "Extra-Terrestrial Exposure Law" was added to the United States Code of Federal Regulations (Title 14, Section 1211) in response to the possibility of biological contamination resulting from the U.S. Apollo Space Program. It was removed in 1991.[122] Scientists consider such a scenario technically possible, but unlikely.[123]

An article in The New York Times discussed the possible threats for humanity of intentionally sending messages aimed at extraterrestrial life into the cosmos in the context of the SETI efforts. Several renowned public figures such as Stephen Hawking and Elon Musk have argued against sending such messages on the grounds that extraterrestrial civilizations with technology are probably far more advanced than humanity and could pose an existential threat to humanity.[124]

Global pandemic

Numerous historical examples of pandemics[125] had a devastating effect on a large number of people. The present, unprecedented scale and speed of human movement make it more difficult than ever to contain an epidemic through local quarantines, and other sources of uncertainty and the evolving nature of the risk means natural pandemics may pose a realistic threat to human civilization.[20]

There are several classes of argument about the likelihood of pandemics. One class of argument about likelihood stems from the history of pandemics, where the limited size of historical pandemics is evidence that larger pandemics are unlikely. This argument has been disputed on several grounds, including the changing risk due to changing population and behavioral patterns among humans, the limited historical record, and the existence of an anthropic bias.[20]

Another argument about the likelihood of pandemics is based on an evolutionary model that predicts that naturally evolving pathogens will ultimately develop an upper limit to their virulence.[126] This is because pathogens with high enough virulence quickly kill their hosts and reduce their chances of spread the infection to new hosts or carriers.[127] This model has limits, however, because the fitness advantage of limited virulence is primarily a function of a limited number of hosts. Any pathogen with a high virulence, high transmission rate and long incubation time may have already caused a catastrophic pandemic before ultimately virulence is limited through natural selection. Additionally, a pathogen that infects humans as a secondary host and primarily infects another species (a zoonosis) has no constraints on its virulence in people, since the accidental secondary infections do not affect its evolution.[128] Lastly, in models where virulence level and rate of transmission are related, high levels of virulence can evolve.[129] Virulence is instead limited by the existence of complex populations of hosts with different susceptibilities to infection, or by some hosts being geographically isolated.[126] The size of the host population and competition between different strains of pathogens can also alter virulence.[130]

Neither of these arguments is applicable to bioengineered pathogens, and this poses entirely different risks of pandemics. Experts have concluded that "Developments in science and technology could significantly ease the development and use of high consequence biological weapons," and these "highly virulent and highly transmissible [bio-engineered pathogens] represent new potential pandemic threats."[131]

Natural climate change

Climate change refers to a lasting change in the Earth's climate. The climate has ranged from ice ages to warmer periods when palm trees grew in Antarctica. It has been hypothesized that there was also a period called "snowball Earth" when all the oceans were covered in a layer of ice. These global climatic changes occurred slowly, near the end of the last Major Ice Age when the climate became more stable. However, abrupt climate change on the decade time scale has occurred regionally. A natural variation into a new climate regime (colder or hotter) could pose a threat to civilization.[132][133]

In the history of the Earth, many ice ages are known to have occurred. An ice age would have a serious impact on civilization because vast areas of land (mainly in North America, Europe, and Asia) could become uninhabitable. Currently, the world is in an interglacial period within a much older glacial event. The last glacial expansion ended about 10,000 years ago, and all civilizations evolved later than this. Scientists do not predict that a natural ice age will occur anytime soon. The amount of heat trapping gases emitted into Earth's Oceans and atmosphere will prevent the next ice age, which otherwise would begin in around 50,000 years, and likely more glacial cycles.[134][135]

Volcanism

Yellowstone sits on top of three overlapping calderas

A geological event such as massive flood basalt, volcanism, or the eruption of a supervolcano[136] could lead to a so-called volcanic winter, similar to a nuclear winter. One such event, the Toba eruption,[137] occurred in Indonesia about 71,500 years ago. According to the Toba catastrophe theory,[138] the event may have reduced human populations to only a few tens of thousands of individuals. Yellowstone Caldera is another such supervolcano, having undergone 142 or more caldera-forming eruptions in the past 17 million years.[139] A massive volcano eruption would eject extraordinary volumes of volcanic dust, toxic and greenhouse gases into the atmosphere with serious effects on global climate (towards extreme global cooling: volcanic winter if short-term, and ice age if long-term) or global warming (if greenhouse gases were to prevail).

When the supervolcano at Yellowstone last erupted 640,000 years ago, the thinnest layers of the ash ejected from the caldera spread over most of the United States west of the Mississippi River and part of northeastern Mexico. The magma covered much of what is now Yellowstone National Park and extended beyond, covering much of the ground from Yellowstone River in the east to the Idaho falls in the west, with some of the flows extending north beyond Mammoth Springs.[140]

According to a recent study, if the Yellowstone caldera erupted again as a supervolcano, an ash layer one to three millimeters thick could be deposited as far away as New York, enough to "reduce traction on roads and runways, short out electrical transformers and cause respiratory problems". There would be centimeters of thickness over much of the U.S. Midwest, enough to disrupt crops and livestock, especially if it happened at a critical time in the growing season. The worst-affected city would likely be Billings, Montana, population 109,000, which the model predicted would be covered with ash estimated as 1.03 to 1.8 meters thick.[141]

The main long-term effect is through global climate change, which reduces the temperature globally by about 5–15 degrees C for a decade, together with the direct effects of the deposits of ash on their crops. A large supervolcano like Toba would deposit one or two meters thickness of ash over an area of several million square kilometers.(1000 cubic kilometers is equivalent to a one-meter thickness of ash spread over a million square kilometers). If that happened in some densely populated agricultural area, such as India, it could destroy one or two seasons of crops for two billion people.[142]

However, Yellowstone shows no signs of a supereruption at present, and it is not certain that a future supereruption will occur there.[143][144]

Research published in 2011 finds evidence that massive volcanic eruptions caused massive coal combustion, supporting models for significant generation of greenhouse gases. Researchers have suggested that massive volcanic eruptions through coal beds in Siberia would generate significant greenhouse gases and cause a runaway greenhouse effect.[145] Massive eruptions can also throw enough pyroclastic debris and other material into the atmosphere to partially block out the sun and cause a volcanic winter, as happened on a smaller scale in 1816 following the eruption of Mount Tambora, the so-called Year Without a Summer. Such an eruption might cause the immediate deaths of millions of people several hundred miles from the eruption, and perhaps billions of death worldwide, due to the failure of the monsoons,[146] resulting in major crop failures causing starvation on a profound scale.[146]

A much more speculative concept is the verneshot: a hypothetical volcanic eruption caused by the buildup of gas deep underneath a craton. Such an event may be forceful enough to launch an extreme amount of material from the crust and mantle into a sub-orbital trajectory.

Proposed mitigation

Planetary management and respecting planetary boundaries have been proposed as approaches to preventing ecological catastrophes. Within the scope of these approaches, the field of geoengineering encompasses the deliberate large-scale engineering and manipulation of the planetary environment to combat or counteract anthropogenic changes in atmospheric chemistry. Space colonization is a proposed alternative to improve the odds of surviving an extinction scenario.[147] Solutions of this scope may require megascale engineering. Food storage has been proposed globally, but the monetary cost would be high. Furthermore, it would likely contribute to the current millions of deaths per year due to malnutrition.[148]

Some survivalists stock survival retreats with multiple-year food supplies.

The Svalbard Global Seed Vault is buried 400 feet (120 m) inside a mountain on an island in the Arctic. It is designed to hold 2.5 billion seeds from more than 100 countries as a precaution to preserve the world's crops. The surrounding rock is −6 °C (21 °F) (as of 2015) but the vault is kept at −18 °C (0 °F) by refrigerators powered by locally sourced coal.[149][150]

More speculatively, if society continues to function and if the biosphere remains habitable, calorie needs for the present human population might in theory be met during an extended absence of sunlight, given sufficient advance planning. Conjectured solutions include growing mushrooms on the dead plant biomass left in the wake of the catastrophe, converting cellulose to sugar, or feeding natural gas to methane-digesting bacteria.[151][152]

Global catastrophic risks and global governance

Insufficient global governance creates risks in the social and political domain, but the governance mechanisms develop more slowly than technological and social change. There are concerns from governments, the private sector, as well as the general public about the lack of governance mechanisms to efficiently deal with risks, negotiate and adjudicate between diverse and conflicting interests. This is further underlined by an understanding of the interconnectedness of global systemic risks.[153] In absence or anticipation of global governance, national governments can act individually to better understand, mitigate and prepare for global catastrophes.[154]

Climate emergency plans

In 2018, the Club of Rome submitted a plan to the European Parliament, urging to address the existential threat from climate change more forcefully, calling for a collaborative climate action afford.[155]

Organizations

The Bulletin of the Atomic Scientists (est. 1945) is one of the oldest global risk organizations, founded after the public became alarmed by the potential of atomic warfare in the aftermath of WWII. It studies risks associated with nuclear war and energy and famously maintains the Doomsday Clock established in 1947. The Foresight Institute (est. 1986) examines the risks of nanotechnology and its benefits. It was one of the earliest organizations to study the unintended consequences of otherwise harmless technology gone haywire at a global scale. It was founded by K. Eric Drexler who postulated "grey goo".[156][157]

Beginning after 2000, a growing number of scientists, philosophers and tech billionaires created organizations devoted to studying global risks both inside and outside of academia.[158]

Independent non-governmental organizations (NGOs) include the Machine Intelligence Research Institute (est. 2000), which aims to reduce the risk of a catastrophe caused by artificial intelligence,[159] with donors including Peter Thiel and Jed McCaleb.[160] The Nuclear Threat Initiative (est. 2001) seeks to reduce global threats from nuclear, biological and chemical threats, and containment of damage after an event.[161] It maintains a nuclear material security index.[162] The Lifeboat Foundation (est. 2009) funds research into preventing a technological catastrophe.[163] Most of the research money funds projects at universities.[164] The Global Catastrophic Risk Institute (est. 2011) is a think tank for catastrophic risk. It is funded by the NGO Social and Environmental Entrepreneurs. The Global Challenges Foundation (est. 2012), based in Stockholm and founded by Laszlo Szombatfalvy, releases a yearly report on the state of global risks.[18][19] The Future of Life Institute (est. 2014) aims to support research and initiatives for safeguarding life considering new technologies and challenges facing humanity.[165] Elon Musk is one of its biggest donors.[166] The Center on Long-Term Risk (est. 2016), formerly known as the Foundational Research Institute, is a British organization focused on reducing risks of astronomical suffering (s-risks) from emerging technologies.[167]

University-based organizations include the Future of Humanity Institute (est. 2005) which researches the questions of humanity's long-term future, particularly existential risk. It was founded by Nick Bostrom and is based at Oxford University. The Centre for the Study of Existential Risk (est. 2012) is a Cambridge-based organization which studies four major technological risks: artificial intelligence, biotechnology, global warming and warfare. All are man-made risks, as Huw Price explained to the AFP news agency, "It seems a reasonable prediction that some time in this or the next century intelligence will escape from the constraints of biology". He added that when this happens "we're no longer the smartest things around," and will risk being at the mercy of "machines that are not malicious, but machines whose interests don't include us."[168] Stephen Hawking was an acting adviser. The Millennium Alliance for Humanity and the Biosphere is a Stanford University-based organization focusing on many issues related to global catastrophe by bringing together members of academic in the humanities.[169][170] It was founded by Paul Ehrlich among others.[171] Stanford University also has the Center for International Security and Cooperation focusing on political cooperation to reduce global catastrophic risk.[172] The Center for Security and Emerging Technology was established in January 2019 at Georgetown's Walsh School of Foreign Service and will focus on policy research of emerging technologies with an initial emphasis on artificial intelligence.[173] They received a grant of 55M USD from Good Ventures as suggested by the Open Philanthropy Project.[173]

Other risk assessment groups are based in or are part of governmental organizations. The World Health Organization (WHO) includes a division called the Global Alert and Response (GAR) which monitors and responds to global epidemic crisis.[174] GAR helps member states with training and coordination of response to epidemics.[175] The United States Agency for International Development (USAID) has its Emerging Pandemic Threats Program which aims to prevent and contain naturally generated pandemics at their source.[176] The Lawrence Livermore National Laboratory has a division called the Global Security Principal Directorate which researches on behalf of the government issues such as bio-security and counter-terrorism.[177]

See also

Notes

  1. Schulte, P.; et al. (5 March 2010). "The Chicxulub Asteroid Impact and Mass Extinction at the Cretaceous-Paleogene Boundary" (PDF). Science. 327 (5970): 1214–1218. Bibcode:2010Sci...327.1214S. doi:10.1126/science.1177265. PMID 20203042.
  2. Bostrom, Nick (2008). Global Catastrophic Risks (PDF). Oxford University Press. p. 1.
  3. Ripple WJ, Wolf C, Newsome TM, Galetti M, Alamgir M, Crist E, Mahmoud MI, Laurance WF (13 November 2017). "World Scientists' Warning to Humanity: A Second Notice". BioScience. 67 (12): 1026–1028. doi:10.1093/biosci/bix125.
  4. Bostrom, Nick (March 2002). "Existential Risks: Analyzing Human Extinction Scenarios and Related Hazards". Journal of Evolution and Technology. 9.
  5. Bostrom, Nick (2013). "Existential Risk Prevention as Global Priority" (PDF). Global Policy. 4 (1): 15–3. doi:10.1111/1758-5899.12002 via Existential Risk.
  6. Bostrom, Nick (2009). "Astronomical Waste: The opportunity cost of delayed technological development". Utilitas. 15 (3): 308–314. CiteSeerX 10.1.1.429.2849. doi:10.1017/s0953820800004076.
  7. Posner, Richard A. (2006). Catastrophe : risk and response. Oxford: Oxford University Press. ISBN 978-0195306477., Introduction, "What is Catastrophe?"
  8. "Observation Selection Effects and Global Catastrophic Risks", Milan Cirkovic, 2008
  9. Toby Ord (2020). The precipice: Existential risk and the future of humanity. ISBN 9780316484893. Europe survived losing 25 to 50 percent of its population in the Black Death, while keeping civilization firmly intact
  10. Matheny, Jason Gaverick (2007). "Reducing the Risk of Human Extinction" (PDF). Risk Analysis. 27 (5): 1335–1344. doi:10.1111/j.1539-6924.2007.00960.x. PMID 18076500.
  11. Asher, D.J.; Bailey, M.E.; Emel'yanenko, V.; Napier, W.M. (2005). "Earth in the cosmic shooting gallery" (PDF). The Observatory. 125: 319–322. Bibcode:2005Obs...125..319A.
  12. Ambrose 1998; Rampino & Ambrose 2000, pp. 71, 80.
  13. Rampino, M.R.; Ambrose, S.H. (2002). "Super eruptions as a threat to civilizations on Earth-like planets" (PDF). Icarus. 156 (2): 562–569. Bibcode:2002Icar..156..562R. doi:10.1006/icar.2001.6808.
  14. Knowles, Hannah (January 23, 2020). "'Doomsday Clock is 100 seconds to midnight, the symbolic hour of the apocalypse". The Washington Post.
  15. Rowe, Thomas; Beard, Simon (2018). "Probabilities, methodologies and the evidence base in existential risk assessments" (PDF). Working Paper, Centre for the Study of Existential Risk. Retrieved 26 August 2018.
  16. Global Catastrophic Risks Survey, Technical Report, 2008, Future of Humanity Institute
  17. Global Catastrophic Risks Survey, Technical Report, 2008, Future of Humanity Institute
  18. Meyer, Robinson (April 29, 2016). "Human Extinction Isn't That Unlikely". The Atlantic. Boston, Massachusetts: Emerson Collective. Retrieved April 30, 2016.
  19. "Global Challenges Foundation website". globalchallenges.org. Retrieved April 30, 2016.
  20. Manheim, David (2018). "Questioning Estimates of Natural Pandemic Risk". Health Security. 16 (6): 381–390. doi:10.1089/hs.2018.0039. PMC 6306648. PMID 30489178.
  21. Jebari, Karim (2014). "Existential Risks: Exploring a Robust Risk Reduction Strategy" (PDF). Science and Engineering Ethics. 21 (3): 541–54. doi:10.1007/s11948-014-9559-3. PMID 24891130. Retrieved 26 August 2018.
  22. Parfit, Derek (1984). Reasons and Persons. Oxford University Press. pp. 453–454.
  23. Carrington, Damian (21 February 2000). "Date set for desert Earth". BBC News Online.
  24. Weitzman, Martin (2009). "On modeling and interpreting the economics of catastrophic climate change" (PDF). The Review of Economics and Statistics. 91 (1): 1–19. doi:10.1162/rest.91.1.1.
  25. Posner, Richard (2004). Catastrophe: Risk and Response. Oxford University Press.
  26. Yudkowsky, Eliezer (2008). "Cognitive Biases Potentially Affecting Judgment of Global Risks" (PDF). Global Catastrophic Risks: 91–119. Bibcode:2008gcr..book...86Y.
  27. Desvousges, W.H., Johnson, F.R., Dunford, R.W., Boyle, K.J., Hudson, S.P., and Wilson, N. 1993, Measuring natural resource damages with contingent valuation: tests of validity and reliability. In Hausman, J.A. (ed), Contingent Valuation:A Critical Assessment, pp. 91–159 (Amsterdam: North Holland).
  28. IPCC (11 November 2013): D. "Understanding the Climate System and its Recent Changes", in: Summary for Policymakers (finalized version) Archived 2017-03-09 at the Wayback Machine, in: IPCC AR5 WG1 2013, p. 13
  29. "Global Catastrophic Risks: a summary". 2019-08-11.
  30. "'Terminator center' to open at Cambridge University". Fox News. 2012-11-26.
  31. "Frequently Asked Questions". Existential Risk. Future of Humanity Institute. Retrieved 26 July 2013.
  32. Bill Joy, Why the future doesn't need us. Wired magazine.
  33. Nick Bostrom 2002 "Ethical Issues in Advanced Artificial Intelligence"
  34. Bostrom, Nick. Superintelligence: Paths, Dangers, Strategies.
  35. Rawlinson, Kevin (2015-01-29). "Microsoft's Bill Gates insists AI is a threat". BBC News. Retrieved 30 January 2015.
  36. Scientists Worry Machines May Outsmart Man by John Markoff, The New York Times, July 26, 2009.
  37. Gaming the Robot Revolution: A military technology expert weighs in on Terminator: Salvation., By P. W. Singer, slate.com Thursday, May 21, 2009.
  38. robot page, engadget.com.
  39. Grace, Katja (2017). "When Will AI Exceed Human Performance? Evidence from AI Experts". Journal of Artificial Intelligence Research. arXiv:1705.08807. Bibcode:2017arXiv170508807G.
  40. Yudkowsky, Eliezer (2008). Artificial Intelligence as a Positive and Negative Factor in Global Risk. Bibcode:2008gcr..book..303Y. Retrieved 26 July 2013.
  41. Ali Noun; Christopher F. Chyba (2008). "Chapter 20: Biotechnology and biosecurity". In Bostrom, Nick; Cirkovic, Milan M. (eds.). Global Catastrophic Risks. Oxford University Press.
  42. Sandberg, Anders. "The five biggest threats to human existence". theconversation.com. Retrieved 13 July 2014.
  43. Jackson, Ronald J.; Ramsay, Alistair J.; Christensen, Carina D.; Beaton, Sandra; Hall, Diana F.; Ramshaw, Ian A. (2001). "Expression of Mouse Interleukin-4 by a Recombinant Ectromelia Virus Suppresses Cytolytic Lymphocyte Responses and Overcomes Genetic Resistance to Mousepox". Journal of Virology. 75 (3): 1205–1210. doi:10.1128/jvi.75.3.1205-1210.2001. PMC 114026. PMID 11152493.
  44. UCLA Engineering (June 28, 2017). "Scholars assess threats to civilization, life on Earth". UCLA. Retrieved June 30, 2017.
  45. Graham, Chris (July 11, 2017). "Earth undergoing sixth 'mass extinction' as humans spur 'biological annihilation' of wildlife". The Telegraph. Retrieved October 20, 2017.
  46. Evans-Pritchard, Ambrose (6 February 2011). "Einstein was right - honey bee collapse threatens global food security". The Daily Telegraph. London.
  47. Lovgren, Stefan. "Mystery Bee Disappearances Sweeping U.S." National Geographic News. URL accessed March 10, 2007.
  48. Carrington, Damian (20 October 2017). "Global pollution kills 9m a year and threatens 'survival of human societies'". The Guardian. London, UK. Retrieved 20 October 2017.
  49. Bostrom 2002, section 4.8
  50. Richard Hamming (1998). "Mathematics on a Distant Planet". The American Mathematical Monthly. 105 (7): 640–650. doi:10.1080/00029890.1998.12004938. JSTOR 2589247.
  51. "Report LA-602, Ignition of the Atmosphere With Nuclear Bombs" (PDF). Retrieved 2011-10-19.
  52. New Scientist, 28 August 1999: "A Black Hole Ate My Planet"
  53. Konopinski, E. J; Marvin, C.; Teller, Edward (1946). "Ignition of the Atmosphere with Nuclear Bombs" (PDF) (Declassified February 1973) (LA–602). Los Alamos National Laboratory. Retrieved 23 November 2008. Cite journal requires |journal= (help)
  54. "Statement by the Executive Committee of the DPF on the Safety of Collisions at the Large Hadron Collider." Archived 2009-10-24 at the Wayback Machine
  55. "Safety at the LHC". Archived from the original on 2008-05-13. Retrieved 2008-06-18.
  56. J. Blaizot et al., "Study of Potentially Dangerous Events During Heavy-Ion Collisions at the LHC", CERN library record CERN Yellow Reports Server (PDF)
  57. Eric Drexler, Engines of Creation, ISBN 0-385-19973-2, available online
  58. Georgescu-Roegen, Nicholas (1971). The Entropy Law and the Economic Process (Full book accessible in three parts at Scribd). Cambridge, Massachusetts: Harvard University Press. ISBN 978-0674257801.
  59. Daly, Herman E., ed. (1980). Economics, Ecology, Ethics. Essays Towards a Steady-State Economy (PDF contains only the introductory chapter of the book) (2nd ed.). San Francisco: W.H. Freeman and Company. ISBN 978-0716711780.
  60. Rifkin, Jeremy (1980). Entropy: A New World View (PDF). New York: The Viking Press. ISBN 978-0670297177. Archived from the original (PDF contains only the title and contents pages of the book) on 2016-10-18.
  61. Boulding, Kenneth E. (1981). Evolutionary Economics. Beverly Hills: Sage Publications. ISBN 978-0803916487.
  62. Martínez-Alier, Juan (1987). Ecological Economics: Energy, Environment and Society. Oxford: Basil Blackwell. ISBN 978-0631171461.
  63. Gowdy, John M.; Mesner, Susan (1998). "The Evolution of Georgescu-Roegen's Bioeconomics" (PDF). Review of Social Economy. 56 (2): 136–156. doi:10.1080/00346769800000016.
  64. Schmitz, John E.J. (2007). The Second Law of Life: Energy, Technology, and the Future of Earth As We Know It (Author's science blog, based on his textbook). Norwich: William Andrew Publishing. ISBN 978-0815515371.
  65. Kerschner, Christian (2010). "Economic de-growth vs. steady-state economy" (PDF). Journal of Cleaner Production. 18 (6): 544–551. doi:10.1016/j.jclepro.2009.10.019.
  66. Perez-Carmona, Alexander (2013). "Growth: A Discussion of the Margins of Economic and Ecological Thought". In Meuleman, Louis (ed.). Transgovernance. Advancing Sustainability Governance. Heidelberg: Springer. pp. 83–161. doi:10.1007/978-3-642-28009-2_3. ISBN 9783642280085.
  67. Dirzo, Rodolfo; Hillary S. Young; Mauro Galetti; Gerardo Ceballos; Nick J. B. Isaac; Ben Collen (2014). "Defaunation in the Anthropocene" (PDF). Science. 345 (6195): 401–406. Bibcode:2014Sci...345..401D. doi:10.1126/science.1251817. PMID 25061202.
  68. Chris Phoenix; Mike Treder (2008). "Chapter 21: Nanotechnology as global catastrophic risk". In Bostrom, Nick; Cirkovic, Milan M. (eds.). Global catastrophic risks. Oxford: Oxford University Press. ISBN 978-0-19-857050-9.
  69. "Frequently Asked Questions - Molecular Manufacturing". foresight.org. Archived from the original on 2014-04-26. Retrieved 19 July 2014.
  70. Drexler, Eric. "A Dialog on Dangers". foresight.org. Retrieved 19 July 2014.
  71. Drexler, Eric. "ENGINES OF DESTRUCTION (Chapter 11)". e-drexler.com. Retrieved 19 July 2014.
  72. "Dangers of Molecular Manufacturing". crnano.org. Retrieved 19 July 2014.
  73. "The Need for International Control". crnano.org. Retrieved 19 July 2014.
  74. "Technical Restrictions May Make Nanotechnology Safer". crnano.org. Retrieved 19 July 2014.
  75. Joseph, Lawrence E. (2007). Apocalypse 2012. New York: Broadway. p. 6. ISBN 978-0-7679-2448-1.
  76. Rincon, Paul (2004-06-09). "Nanotech guru turns back on 'goo'". BBC News. Retrieved 2012-03-30.
  77. Hapgood, Fred (November 1986). "Nanotechnology: Molecular Machines that Mimic Life" (PDF). Omni. Retrieved 19 July 2014.
  78. "Leading nanotech experts put 'grey goo' in perspective". crnano.org. Retrieved 19 July 2014.
  79. Hellman, Martin (April 29, 1985). "On the Probability of Nuclear War". Houston Post. Houston, Texas: MediaNews Group.
  80. Cohen, Avner; Lee, Steven (1986). Nuclear Weapons and the Future of Humanity: The Fundamental Questions. Lanham, Maryland: Rowman & Littlefield. p. 237. ISBN 978-0847672585. gYmPp6lZqtMC.
  81. Federation of American Scientists (28 April 2015). "Status of World Nuclear Forces". Federation of American Scientists. Archived from the original on 18 June 2015. Retrieved 4 June 2015.
  82. "Atmospheric effects and societal consequences of regional-scale nuclear conflicts and acts of individual nuclear terrorism", Atmospheric Chemistry and Physics
  83. Bostrom 2002, section 4.2.
  84. Martin, Brian (1982). "Critique of nuclear extinction". Journal of Peace Research. 19 (4): 287–300. doi:10.1177/002234338201900401. Retrieved 25 October 2014.
  85. Shulman, Carl (5 Nov 2012). "Nuclear winter and human extinction: Q&A with Luke Oman". Overcoming Bias. Retrieved 25 October 2014.
  86. "The end of India's green revolution?". BBC News. 2006-05-29. Retrieved 2012-01-31.
  87. admin (2000-04-08). "Food First/Institute for Food and Development Policy". Foodfirst.org. Archived from the original on July 14, 2009. Retrieved 2012-01-31.
  88. "How peak oil could lead to starvation". 2009-05-27. Archived from the original on May 27, 2009. Retrieved 2012-01-31.
  89. "Eating Fossil Fuels". EnergyBulletin.net. 2003-10-02. Archived from the original on 2012-02-12. Retrieved 2012-01-31.
  90. The Oil Drum: Europe. "Agriculture Meets Peak Oil". Europe.theoildrum.com. Retrieved 2012-01-31.
  91. "Drawing Momentum from the Crash" by Dale Allen Pfeiffer
  92. Neff, R. A.; Parker, C. L.; Kirschenmann, F. L.; Tinch, J.; Lawrence, R. S. (September 2011). "Peak Oil, Food Systems, and Public Health". American Journal of Public Health. 101 (9): 1587–1597. doi:10.2105/AJPH.2011.300123. PMC 3154242. PMID 21778492.
  93. "Former BP geologist: peak oil is here and it will 'break economies'". The Guardian. 23 December 2013.
  94. "Cereal Disease Laboratory : Ug99 an emerging virulent stem rust race". Ars.usda.gov. Retrieved 2012-01-31.
  95. "Durable Rust Resistance in Wheat". Wheatrust.cornell.edu. Retrieved 2012-01-31.
  96. Gehrels, Tom; Matthews, Mildred Shapley; Schumann, A. M. (1994). Hazards Due to Comets and Asteroids. University of Arizona Press. p. 71. ISBN 9780816515059.
  97. "How Big Would A Meteorite Have To Be To Wipe Out All Human Life?". Popular Science. 26 February 2015. Retrieved 13 February 2018.
  98. Bostrom 2002, section 4.10
  99. Rumpf, Clemens (2016-12-20). Asteroid Impact Risk. University of Southampton (phd).
  100. "Committee on Science, Space and Technology" (PDF). NASA. 19 March 2013. Retrieved 13 February 2018.
  101. Harper, Paul (28 April 2018). "Earth will be hit by asteroid with 100% CERTAINTY – space experts warn - EXPERTS have warned it is "100pc certain" Earth will be devastated by an asteroid as millions are hurling towards the planet undetected". Daily Star. Retrieved 23 June 2018.
  102. Homer, Aaron (28 April 2018). "Earth Will Be Hit By An Asteroid With 100 Percent Certainty, Says Space-Watching Group B612 - The group of scientists and former astronauts is devoted to defending the planet from a space apocalypse". Inquisitr. Retrieved 23 June 2018.
  103. Stanley-Becker, Isaac (15 October 2018). "Stephen Hawking feared race of 'superhumans' able to manipulate their own DNA". The Washington Post. Retrieved 26 November 2018.
  104. Haldevang, Max de (14 October 2018). "Stephen Hawking left us bold predictions on AI, superhumans, and aliens". Quartz. Retrieved 26 November 2018.
  105. Bogdan, Dennis (18 June 2018). "Comment - Better Way To Avoid Devastating Asteroids Needed?". The New York Times. Retrieved 26 November 2018.
  106. Staff (21 June 2018). "National Near-Earth Object Preparedness Strategy Action Plan" (PDF). White House. Retrieved 23 June 2018.
  107. Mandelbaum, Ryan F. (21 June 2018). "America Isn't Ready to Handle a Catastrophic Asteroid Impact, New Report Warns". Gizmodo. Retrieved 23 June 2018.
  108. Myhrvold, Nathan (22 May 2018). "An empirical examination of WISE/NEOWISE asteroid analysis and results". Icarus. 314: 64–97. Bibcode:2018Icar..314...64M. doi:10.1016/j.icarus.2018.05.004.
  109. Chang, Kenneth (14 June 2018). "Asteroids and Adversaries: Challenging What NASA Knows About Space Rocks - Two years ago, NASA dismissed and mocked an amateur's criticisms of its asteroids database. Now Nathan Myhrvold is back, and his papers have passed peer review". The New York Times. Retrieved 23 June 2018.
  110. Chang, Kenneth (14 June 2018). "Asteroids and Adversaries: Challenging What NASA Knows About Space Rocks - Relevant Comments". The New York Times. Retrieved 23 June 2018.
  111. U.S.Congress (19 March 2013). "Threats From Space: a Review of U.S. Government Efforts to Track and mitigate Asteroids and Meteors (Part I and Part II) – Hearing Before the Committee on Science, Space, and Technology House of Representatives One Hundred Thirteenth Congress First Session" (PDF). United States Congress. p. 147. Retrieved 26 November 2018.
  112. Ken Croswell, Will Mercury Hit Earth Someday?, Skyandtelescope.com April 24, 2008, accessed April 26, 2008
  113. Sackmann, I.-Juliana; Boothroyd, Arnold I.; Kraemer, Kathleen E. (1993), "Our Sun. III. Present and Future", The Astrophysical Journal, 418 (7491): 457–68, Bibcode:1993ApJ...418..457S, doi:10.1086/173407
  114. M.S. Turner; F. Wilczek (1982). "Is our vacuum metastable?" (PDF). Nature. 298 (5875): 633–634. Bibcode:1982Natur.298..633T. doi:10.1038/298633a0. Retrieved 2015-10-31.
  115. M. Tegmark; N. Bostrom (2005). "Is a doomsday catastrophe likely?" (PDF). Nature. 438 (5875): 754. Bibcode:2005Natur.438..754T. doi:10.1038/438754a. PMID 16341005. Archived from the original (PDF) on 2014-04-09. Retrieved 2016-03-16.
  116. Bostrom 2002, section 4.7
  117. Lassen, B (2013). "Is livestock production prepared for an electrically paralysed world?". J Sci Food Agric. 93 (1): 2–4. doi:10.1002/jsfa.5939. PMID 23111940.
  118. Coleman, Sidney; De Luccia, Frank (1980-06-15). "Gravitational effects on and of vacuum decay" (PDF). Physical Review D. D21 (12): 3305–3315. Bibcode:1980PhRvD..21.3305C. doi:10.1103/PhysRevD.21.3305.
  119. Siegel, Ethan (2020). "Ask Ethan: Will The Earth Eventually Be Swallowed By The Sun?". Forbes/Starts With A Bang. Retrieved 14 May 2020.
  120. Schroeder, K.-P.; Connon Smith, Robert (1 May 2008). "Distant future of the Sun and Earth revisited". Monthly Notices of the Royal Astronomical Society. 386 (1): 155–163. Bibcode:2008MNRAS.386..155S. doi:10.1111/j.1365-2966.2008.13022.x.
  121. Twenty ways the world could end suddenly Archived 2004-09-24 at the Wayback Machine, Discover Magazine
  122. Urban Legends Reference Pages: Legal Affairs (E.T. Make Bail)
  123. Bostrom 2002, section 7.2
  124. Johnson, Steven (2017-06-28). "Greetings, E.T. (Please Don't Murder Us.)". The New York Times. ISSN 0362-4331. Retrieved 2017-06-29.
  125. "Near Apocalypse Causing Diseases, a Historical Look". postapocalypticsurvival.com. Retrieved 2012-05-05.
  126. Frank SA (March 1996). "Models of parasite virulence" (PDF). Q Rev Biol. 71 (1): 37–78. doi:10.1086/419267. PMID 8919665. Archived from the original (PDF) on 2015-05-18.
  127. Brown NF, Wickham ME, Coombes BK, Finlay BB (May 2006). "Crossing the Line: Selection and Evolution of Virulence Traits". PLOS Pathogens. 2 (5): e42. doi:10.1371/journal.ppat.0020042. PMC 1464392. PMID 16733541.
  128. Gandon S (March 2004). "Evolution of multihost parasites". Evolution. 58 (3): 455–69. doi:10.1111/j.0014-3820.2004.tb01669.x. PMID 15119430.
  129. Ebert D, Bull JJ (January 2003). "Challenging the trade-off model for the evolution of virulence: is virulence management feasible?". Trends Microbiol. 11 (1): 15–20. doi:10.1016/S0966-842X(02)00003-3. PMID 12526850.
  130. André JB, Hochberg ME (July 2005). "Virulence evolution in emerging infectious diseases". Evolution. 59 (7): 1406–12. doi:10.1554/05-111. PMID 16153027.
  131. "Powerful actor, high impact bio-threats. Wilton Park. Wednesday 7 – Friday 9 November 2018"
  132. Haines, A.; Kovats, R.S.; Campbell-Lendrum, D.; Corvalan, C. (July 2006). "Climate change and human health: Impacts, vulnerability and public health". Public Health. 120 (7): 585–596. doi:10.1016/j.puhe.2006.01.002. ISSN 0033-3506. PMID 16542689.
  133. Epstein, Paul R. (2005-10-06). "Climate Change and Human Health". New England Journal of Medicine. 353 (14): 1433–1436. doi:10.1056/nejmp058079. ISSN 0028-4793. PMC 2636266. PMID 16207843.
  134. "Global Warming Good News: No More Ice Ages". LiveScience. 2007.
  135. "Human-made climate change suppresses the next ice age". Potsdam Institute for Climate Impact Research in Germany. 2016.
  136. Kate Ravilious (2005-04-14). "What a way to go". The Guardian.
  137. 2012 Admin (2008-02-04). "Toba Supervolcano". 2012 Final Fantasy. Archived from the original on 2010-08-22.
  138. Science Reference. "Toba Catastrophe Theory". Science Daily. Archived from the original on 2015-04-04. Retrieved 2018-02-28.
  139. Greg Breining (10 November 2007). "The Next Big Blast". Super Volcano: The Ticking Time Bomb Beneath Yellowstone National Park. MBI Publishing Company. ISBN 978-1-61673-898-3.
  140. Greg Breining (10 November 2007). "Distant Death". Super Volcano: The Ticking Time Bomb Beneath Yellowstone National Park. MBI Publishing Company. ISBN 978-1-61673-898-3.
  141. "Modeling the Ash Distribution of a Yellowstone Supereruption". USGS Volcanic Observatory.
  142. "Extreme Geohazards: Reducing the Disaster Risk and Increasing Resilience" (PDF). European Space Foundation. Archived from the original (PDF) on 2018-02-17. Retrieved 2018-02-16.
  143. "Questions About Future Volcanic Activity at Yellowstone". USGA Volcanic Observatory FAQ.
  144. "Steam Explosions, Earthquakes, and Volcanic Eruptions—What's in Yellowstone's Future?". USGS Yellowstone Volcanic Observatory. The USGS puts it like this: "If another large caldera-forming eruption were to occur at Yellowstone, its effects would be worldwide. Thick ash deposits would bury vast areas of the United States, and injection of huge volumes of volcanic gases into the atmosphere could drastically affect global climate. Fortunately, the Yellowstone volcanic system shows no signs that it is headed toward such an eruption. The probability of a large caldera-forming eruption within the next few thousand years is exceedingly low."
  145. "World's biggest extinction event: Massive volcanic eruption, burning coal and accelerated greenhouse gas choked out life -- ScienceDaily". Https. Retrieved 28 September 2016.
  146. Breining, Greg (2007). "The Next Big Blast". Super Volcano: The Ticking Time Bomb Beneath Yellowstone National Park. St. Paul, MN.: Voyageur Press. p. 256 pg. ISBN 978-0-7603-2925-2.
  147. "Mankind must abandon earth or face extinction: Hawking", physorg.com, August 9, 2010, retrieved 2012-01-23
  148. Smil, Vaclav (2003). The Earth's Biosphere: Evolution, Dynamics, and Change. MIT Press. p. 25. ISBN 978-0-262-69298-4.
  149. Lewis Smith (2008-02-27). "Doomsday vault for world's seeds is opened under Arctic mountain". The Times Online. London. Archived from the original on 2008-05-12.
  150. Suzanne Goldenberg (May 20, 2015). "The doomsday vault: the seeds that could save a post-apocalyptic world". The Guardian. Retrieved June 30, 2017.
  151. "Here's how the world could end—and what we can do about it". Science | AAAS. 8 July 2016. Retrieved 23 March 2018.
  152. Denkenberger, David C.; Pearce, Joshua M. (September 2015). "Feeding everyone: Solving the food crisis in event of global catastrophes that kill crops or obscure the sun" (PDF). Futures. 72: 57–68. doi:10.1016/j.futures.2014.11.008.
  153. "Global Challenges Foundation | Understanding Global Systemic Risk". globalchallenges.org. Archived from the original on 2017-08-16. Retrieved 2017-08-15.
  154. "Global Catastrophic Risk Policy |". gcrpolicy.com. Retrieved 2019-08-11.
  155. Club of Rome (2018). "The Club of Rome Launches Its Climate Emergency Plan At The European Parliament".
  156. Fred Hapgood (November 1986). "Nanotechnology: Molecular Machines that Mimic Life" (PDF). Omni. Retrieved June 5, 2015.
  157. Giles, Jim (2004). "Nanotech takes small step towards burying 'grey goo'". Nature. 429 (6992): 591. Bibcode:2004Natur.429..591G. doi:10.1038/429591b. PMID 15190320.
  158. Sophie McBain (September 25, 2014). "Apocalypse soon: the scientists preparing for the end times". New Statesman. Retrieved June 5, 2015.
  159. "Reducing Long-Term Catastrophic Risks from Artificial Intelligence". Machine Intelligence Research Institute. Retrieved June 5, 2015. The Machine Intelligence Research Institute aims to reduce the risk of a catastrophe, should such an event eventually occur.
  160. Angela Chen (September 11, 2014). "Is Artificial Intelligence a Threat?". The Chronicle of Higher Education. Retrieved June 5, 2015.
  161. "Nuclear Threat Initiative". Retrieved June 5, 2015.
  162. Alexander Sehmar (May 31, 2015). "Isis could obtain nuclear weapon from Pakistan, warns India". The Independent. Retrieved June 5, 2015.
  163. "About the Lifeboat Foundation". The Lifeboat Foundation. Retrieved 26 April 2013.
  164. Ashlee Vance (July 20, 2010). "The Lifeboat Foundation: Battling Asteroids, Nanobots and A.I." New York Times. Retrieved June 5, 2015.
  165. "The Future of Life Institute". Retrieved May 5, 2014.
  166. Nick Bilton (May 28, 2015). "Ava of 'Ex Machina' Is Just Sci-Fi (for Now)". New York Times. Retrieved June 5, 2015.
  167. "About Us". Center on Long-Term Risk. Retrieved May 17, 2020. We currently focus on efforts to reduce the worst risks of astronomical suffering (s-risks) from emerging technologies, with a focus on transformative artificial intelligence.
  168. Hui, Sylvia (25 November 2012). "Cambridge to study technology's risks to humans". Associated Press. Archived from the original on 1 December 2012. Retrieved 30 January 2012.
  169. Scott Barrett (2014). Environment and Development Economics: Essays in Honour of Sir Partha Dasgupta. Oxford University Press. p. 112. ISBN 9780199677856. Retrieved June 5, 2015.
  170. "Millennium Alliance for Humanity & The Biosphere". Millennium Alliance for Humanity & The Biosphere. Retrieved June 5, 2015.
  171. Guruprasad Madhavan (2012). Practicing Sustainability. Springer Science & Business Media. p. 43. ISBN 9781461443483. Retrieved June 5, 2015.
  172. "Center for International Security and Cooperation". Center for International Security and Cooperation. Retrieved June 5, 2015.
  173. https://www.facebook.com/profile.php?id=1216916378. "Georgetown launches think tank on security and emerging technology". Washington Post. Retrieved 2019-03-12.
  174. "Global Alert and Response (GAR)". World Health Organization. Retrieved June 5, 2015.
  175. Kelley Lee (2013). Historical Dictionary of the World Health Organization. Rowman & Littlefield. p. 92. ISBN 9780810878587. Retrieved June 5, 2015.
  176. "USAID Emerging Pandemic Threats Program". USAID. Archived from the original on 2014-10-22. Retrieved June 5, 2015.
  177. "Global Security". Lawrence Livermore National Laboratory. Retrieved June 5, 2015.

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