Because most diversity and biomass on Earth is microbial, and thus difficult to measure, recorded extinction events affect the easily observed, biologically complex component of the biosphere rather than the total diversity and abundance of life. Extinction occurs at an uneven rate. Based on the fossil record, the background rate of extinctions on Earth is about two to five taxonomic families of marine animals every million years. Marine fossils are mostly used to measure extinction rates because of their superior fossil record and stratigraphic range compared to land animals.
The Great Oxygenation Event, which occurred around 2.45 billion years ago, was probably the first major extinction event. Since the Cambrian explosion five further major mass extinctions have significantly exceeded the background extinction rate. The most recent and arguably best-known, the Cretaceous–Paleogene extinction event, which occurred approximately 66 million years ago (Ma), was a large-scale mass extinction of animal and plant species in a geologically short period of time. In addition to the five major mass extinctions, there are numerous minor ones as well, and the ongoing mass extinction caused by human activity is sometimes called the sixth extinction. Mass extinctions seem to be a mainly Phanerozoic phenomenon, with extinction rates low before large complex organisms arose.
Major extinction events
In a landmark paper published in 1982, Jack Sepkoski and David M. Raup
identified five mass extinctions. They were originally identified as
outliers to a general trend of decreasing extinction rates during the
Phanerozoic,
but as more stringent statistical tests have been applied to the
accumulating data, it has been established that multicellular animal
life has experienced five major and many minor mass extinctions.
The "Big Five" cannot be so clearly defined, but rather appear to
represent the largest (or some of the largest) of a relatively smooth
continuum of extinction events.
- Ordovician–Silurian extinction events (End Ordovician or O–S): 450–440 Ma (million years ago) at the Ordovician–Silurian transition. Two events occurred that killed off 27% of all families, 57% of all genera and 60% to 70% of all species. Together they are ranked by many scientists as the second largest of the five major extinctions in Earth's history in terms of percentage of genera that became extinct.
- Late Devonian extinction: 375–360 Ma near the Devonian–Carboniferous transition. At the end of the Frasnian Age in the later part(s) of the Devonian Period, a prolonged series of extinctions eliminated about 19% of all families, 50% of all genera and at least 70% of all species. This extinction event lasted perhaps as long as 20 million years, and there is evidence for a series of extinction pulses within this period.
- Permian–Triassic extinction event (End Permian): 252 Ma at the Permian–Triassic transition. Earth's largest extinction killed 57% of all families, 83% of all genera and 90% to 96% of all species (53% of marine families, 84% of marine genera, about 96% of all marine species and an estimated 70% of land species, including insects). The highly successful marine arthropod, the trilobite, became extinct. The evidence regarding plants is less clear, but new taxa became dominant after the extinction. The "Great Dying" had enormous evolutionary significance: on land, it ended the primacy of mammal-like reptiles. The recovery of vertebrates took 30 million years, but the vacant niches created the opportunity for archosaurs to become ascendant. In the seas, the percentage of animals that were sessile dropped from 67% to 50%. The whole late Permian was a difficult time for at least marine life, even before the "Great Dying".
- Triassic–Jurassic extinction event (End Triassic): 201.3 Ma at the Triassic–Jurassic transition. About 23% of all families, 48% of all genera (20% of marine families and 55% of marine genera) and 70% to 75% of all species became extinct. Most non-dinosaurian archosaurs, most therapsids, and most of the large amphibians were eliminated, leaving dinosaurs with little terrestrial competition. Non-dinosaurian archosaurs continued to dominate aquatic environments, while non-archosaurian diapsids continued to dominate marine environments. The Temnospondyl lineage of large amphibians also survived until the Cretaceous in Australia (e.g., Koolasuchus).
- Cretaceous–Paleogene extinction event (End Cretaceous, K–Pg extinction, or formerly K–T extinction): 66 Ma at the Cretaceous (Maastrichtian) – Paleogene (Danian) transition interval. The event formerly called the Cretaceous-Tertiary or K–T extinction or K–T boundary is now officially named the Cretaceous–Paleogene (or K–Pg) extinction event. About 17% of all families, 50% of all genera and 75% of all species became extinct. In the seas all the ammonites, plesiosaurs and mosasaurs disappeared and the percentage of sessile animals (those unable to move about) was reduced to about 33%. All non-avian dinosaurs became extinct during that time. The boundary event was severe with a significant amount of variability in the rate of extinction between and among different clades. Mammals and birds, the latter descended from theropod dinosaurs, emerged as dominant large land animals.
Despite the popularization of these five events, there is no definite
line separating them from other extinction events; using different
methods of calculating an extinction's impact can lead to other events
featuring in the top five.
Older fossil records are more difficult to interpret. This is because:
- Older fossils are harder to find as they are usually buried at a considerable depth.
- Dating older fossils is more difficult.
- Productive fossil beds are researched more than unproductive ones, therefore leaving certain periods unresearched.
- Prehistoric environmental events can disturb the deposition process.
- The preservation of fossils varies on land, but marine fossils tend to be better preserved than their sought after land-based counterparts.
It has been suggested that the apparent variations in marine
biodiversity may actually be an artifact, with abundance estimates
directly related to quantity of rock available for sampling from
different time periods. However, statistical analysis shows that this can only account for 50% of the observed pattern, and other evidence (such as fungal spikes)
provides reassurance that most widely accepted extinction events are
real. A quantification of the rock exposure of Western Europe indicates
that many of the minor events for which a biological explanation has
been sought are most readily explained by sampling bias.
Research completed after the seminal 1982 paper has concluded that a sixth mass extinction event is ongoing:
- Holocene extinction: Currently ongoing. Extinctions have occurred at over 1000 times the background extinction rate since 1900. The mass extinction is a result of human activity. The 2019 global biodiversity assessment by IPBES asserts that 25% of plant and animal species are threatened with extinction.
More recent research has indicated that the End-Capitanian extinction event
likely constitutes a separate extinction event from the
Permian–Triassic extinction event; if so, it would be larger than many
of the "Big Five" extinction events.
List of extinction events
Evolutionary importance
-4500 —
–
-4000 —
–
-3500 —
–
-3000 —
–
-2500 —
–
-2000 —
–
-1500 —
–
-1000 —
–
-500 —
–
0 —
Mass extinctions have sometimes accelerated the evolution of life on Earth.
When dominance of particular ecological niches passes from one group of
organisms to another, it is rarely because the new dominant group is
"superior" to the old and usually because an extinction event eliminates
the old dominant group and makes way for the new one.
For example, mammaliformes ("almost mammals") and then mammals existed throughout the reign of the dinosaurs, but could not compete for the large terrestrial vertebrate niches which dinosaurs monopolized. The end-Cretaceous
mass extinction removed the non-avian dinosaurs and made it possible
for mammals to expand into the large terrestrial vertebrate niches.
Ironically, the dinosaurs themselves had been beneficiaries of a
previous mass extinction, the end-Triassic, which eliminated most of their chief rivals, the crurotarsans.
Another point of view put forward in the Escalation hypothesis
predicts that species in ecological niches with more
organism-to-organism conflict will be less likely to survive
extinctions. This is because the very traits that keep a species
numerous and viable under fairly static conditions become a burden once
population levels fall among competing organisms during the dynamics of
an extinction event.
Furthermore, many groups which survive mass extinctions do not
recover in numbers or diversity, and many of these go into long-term
decline, and these are often referred to as "Dead Clades Walking".
However, clades that survive for a considerable period of time after a
mass extinction, and which were reduced to only a few species, are
likely to have experienced a rebound effect called the "push of the past".
Darwin was firmly of the opinion that biotic interactions, such
as competition for food and space—the ‘struggle for existence’—were of
considerably greater importance in promoting evolution and extinction
than changes in the physical environment. He expressed this in The Origin of Species:
"Species are produced and exterminated by slowly acting causes…and the
most import of all causes of organic change is one which is almost
independent of altered…physical conditions, namely the mutual relation
of organism to organism-the improvement of one organism entailing the
improvement or extermination of others".
Patterns in frequency
It has been suggested variously that extinction events occurred periodically, every 26 to 30 million years, or that diversity fluctuates episodically every ~62 million years.
Various ideas attempt to explain the supposed pattern, including the presence of a hypothetical companion star to the sun,
oscillations in the galactic plane, or passage through the Milky Way's spiral arms.
However, other authors have concluded that the data on marine mass
extinctions do not fit with the idea that mass extinctions are periodic,
or that ecosystems gradually build up to a point at which a mass
extinction is inevitable. Many of the proposed correlations have been argued to be spurious.
Others have argued that there is strong evidence supporting periodicity in a variety of records,
and additional evidence in the form of coincident periodic variation in nonbiological geochemical variables.
Mass extinctions are thought to result when a long-term stress is compounded by a short-term shock. Over the course of the Phanerozoic, individual taxa appear to be less likely to become extinct at any time,
which may reflect more robust food webs as well as less
extinction-prone species and other factors such as continental
distribution.
However, even after accounting for sampling bias, there does appear to
be a gradual decrease in extinction and origination rates during the
Phanerozoic.
This may represent the fact that groups with higher turnover rates are
more likely to become extinct by chance; or it may be an artefact of
taxonomy: families tend to become more speciose, therefore less prone to
extinction, over time; and larger taxonomic groups (by definition) appear earlier in geological time.
It has also been suggested that the oceans have gradually become
more hospitable to life over the last 500 million years, and thus less
vulnerable to mass extinctions, but susceptibility to extinction at a taxonomic level does not appear to make mass extinctions more or less probable.
Causes
There is
still debate about the causes of all mass extinctions. In general, large
extinctions may result when a biosphere under long-term stress
undergoes a short-term shock.
An underlying mechanism appears to be present in the correlation of
extinction and origination rates to diversity. High diversity leads to a
persistent increase in extinction rate; low diversity to a persistent
increase in origination rate. These presumably ecologically controlled
relationships likely amplify smaller perturbations (asteroid impacts,
etc.) to produce the global effects observed.
Identifying causes of specific mass extinctions
A
good theory for a particular mass extinction should: (i) explain all of
the losses, not just focus on a few groups (such as dinosaurs); (ii)
explain why particular groups of organisms died out and why others
survived; (iii) provide mechanisms which are strong enough to cause a
mass extinction but not a total extinction; (iv) be based on events or
processes that can be shown to have happened, not just inferred from the
extinction.
It may be necessary to consider combinations of causes. For example, the marine aspect of the end-Cretaceous
extinction appears to have been caused by several processes which
partially overlapped in time and may have had different levels of
significance in different parts of the world.
Arens and West (2006) proposed a "press / pulse" model in which
mass extinctions generally require two types of cause: long-term
pressure on the eco-system ("press") and a sudden catastrophe ("pulse")
towards the end of the period of pressure.
Their statistical analysis of marine extinction rates throughout the Phanerozoic
suggested that neither long-term pressure alone nor a catastrophe alone
was sufficient to cause a significant increase in the extinction rate.
Most widely supported explanations
Macleod (2001)
summarized the relationship between mass extinctions and events which
are most often cited as causes of mass extinctions, using data from
Courtillot et al. (1996), Hallam (1992) and Grieve et al. (1996):
- Flood basalt events: 11 occurrences, all associated with significant extinctions But Wignall (2001) concluded that only five of the major extinctions coincided with flood basalt eruptions and that the main phase of extinctions started before the eruptions.
- Sea-level falls: 12, of which seven were associated with significant extinctions.
- Asteroid impacts: one large impact is associated with a mass extinction, i.e. the Cretaceous–Paleogene extinction event; there have been many smaller impacts but they are not associated with significant extinctions.
The most commonly suggested causes of mass extinctions are listed below.
Flood basalt events
The formation of large igneous provinces by flood basalt events could have:
- produced dust and particulate aerosols which inhibited photosynthesis and thus caused food chains to collapse both on land and at sea
- emitted sulfur oxides which were precipitated as acid rain and poisoned many organisms, contributing further to the collapse of food chains
- emitted carbon dioxide and thus possibly causing sustained global warming once the dust and particulate aerosols dissipated.
Flood basalt events occur as pulses of activity punctuated by dormant
periods. As a result, they are likely to cause the climate to oscillate
between cooling and warming, but with an overall trend towards warming
as the carbon dioxide they emit can stay in the atmosphere for hundreds
of years.
It is speculated that massive volcanism caused or contributed to the End-Permian, End-Triassic and End-Cretaceous extinctions.
The correlation between gigantic volcanic events expressed in the large
igneous provinces and mass extinctions was shown for the last 260 Myr. Recently such possible correlation was extended for the whole Phanerozoic Eon.
Sea-level falls
These
are often clearly marked by worldwide sequences of contemporaneous
sediments which show all or part of a transition from sea-bed to tidal
zone to beach to dry land – and where there is no evidence that the
rocks in the relevant areas were raised by geological processes such as orogeny.
Sea-level falls could reduce the continental shelf area (the most
productive part of the oceans) sufficiently to cause a marine mass
extinction, and could disrupt weather patterns enough to cause
extinctions on land. But sea-level falls are very probably the result of
other events, such as sustained global cooling or the sinking of the mid-ocean ridges.
Sea-level falls are associated with most of the mass extinctions, including all of the "Big Five"—End-Ordovician, Late Devonian, End-Permian, End-Triassic, and End-Cretaceous.
A study, published in the journal Nature (online June 15, 2008)
established a relationship between the speed of mass extinction events
and changes in sea level and sediment.
The study suggests changes in ocean environments related to sea level
exert a driving influence on rates of extinction, and generally
determine the composition of life in the oceans.
Impact events
The impact of a sufficiently large asteroid or comet could have caused food chains to collapse both on land and at sea by producing dust and particulate aerosols and thus inhibiting photosynthesis. Impacts on sulfur-rich rocks could have emitted sulfur oxides precipitating as poisonous acid rain, contributing further to the collapse of food chains. Such impacts could also have caused megatsunamis and/or global forest fires.
Most paleontologists now agree that an asteroid did hit the Earth
about 66 Ma ago, but there is an ongoing dispute whether the impact was
the sole cause of the Cretaceous–Paleogene extinction event.
Global cooling
Sustained and significant global cooling could kill many polar and temperate species and force others to migrate towards the equator; reduce the area available for tropical
species; often make the Earth's climate more arid on average, mainly by
locking up more of the planet's water in ice and snow. The glaciation cycles of the current ice age
are believed to have had only a very mild impact on biodiversity, so
the mere existence of a significant cooling is not sufficient on its own
to explain a mass extinction.
It has been suggested that global cooling caused or contributed to the End-Ordovician, Permian–Triassic, Late Devonian
extinctions, and possibly others. Sustained global cooling is
distinguished from the temporary climatic effects of flood basalt events
or impacts.
Global warming
This would have the opposite effects: expand the area available for tropical species; kill temperate species or force them to migrate towards the poles;
possibly cause severe extinctions of polar species; often make the
Earth's climate wetter on average, mainly by melting ice and snow and
thus increasing the volume of the water cycle. It might also cause anoxic events in the oceans (see below).
Global warming as a cause of mass extinction is supported by several recent studies.
The most dramatic example of sustained warming is the Paleocene–Eocene Thermal Maximum, which was associated with one of the smaller mass extinctions. It has also been suggested to have caused the Triassic–Jurassic extinction event, during which 20% of all marine families became extinct. Furthermore, the Permian–Triassic extinction event has been suggested to have been caused by warming.
Clathrate gun hypothesis
Clathrates are composites in which a lattice of one substance forms a cage around another. Methane clathrates (in which water molecules are the cage) form on continental shelves.
These clathrates are likely to break up rapidly and release the methane
if the temperature rises quickly or the pressure on them drops
quickly—for example in response to sudden global warming or a sudden drop in sea level or even earthquakes. Methane is a much more powerful greenhouse
gas than carbon dioxide, so a methane eruption ("clathrate gun") could
cause rapid global warming or make it much more severe if the eruption
was itself caused by global warming.
The most likely signature of such a methane eruption would be a sudden decrease in the ratio of carbon-13 to carbon-12
in sediments, since methane clathrates are low in carbon-13; but the
change would have to be very large, as other events can also reduce the
percentage of carbon-13.
It has been suggested that "clathrate gun" methane eruptions were involved in the end-Permian extinction ("the Great Dying") and in the Paleocene–Eocene Thermal Maximum, which was associated with one of the smaller mass extinctions.
Anoxic events
Anoxic events
are situations in which the middle and even the upper layers of the
ocean become deficient or totally lacking in oxygen. Their causes are
complex and controversial, but all known instances are associated with
severe and sustained global warming, mostly caused by sustained massive
volcanism.
It has been suggested that anoxic events caused or contributed to the Ordovician–Silurian, late Devonian, Permian–Triassic and Triassic–Jurassic extinctions, as well as a number of lesser extinctions (such as the Ireviken, Mulde, Lau, Toarcian and Cenomanian–Turonian
events). On the other hand, there are widespread black shale beds from
the mid-Cretaceous which indicate anoxic events but are not associated
with mass extinctions.
The bio-availability of essential trace elements (in particular selenium)
to potentially lethal lows has been shown to coincide with, and likely
have contributed to, at least three mass extinction events in the
oceans, i.e. at the end of the Ordovician, during the Middle and Late
Devonian, and at the end of the Triassic. During periods of low oxygen
concentrations very soluble selenate (Se6+) is converted into much less soluble selenide (Se2-),
elemental Se and organo-selenium complexes. Bio-availability of
selenium during these extinction events dropped to about 1% of the
current oceanic concentration, a level that has been proven lethal to
many extant organisms.
Hydrogen sulfide emissions from the seas
Kump, Pavlov and Arthur (2005) have proposed that during the Permian–Triassic extinction event the warming also upset the oceanic balance between photosynthesising plankton and deep-water sulfate-reducing bacteria, causing massive emissions of hydrogen sulfide which poisoned life on both land and sea and severely weakened the ozone layer, exposing much of the life that still remained to fatal levels of UV radiation.
Oceanic overturn
Oceanic overturn is a disruption of thermo-haline circulation
which lets surface water (which is more saline than deep water because
of evaporation) sink straight down, bringing anoxic deep water to the
surface and therefore killing most of the oxygen-breathing organisms
which inhabit the surface and middle depths. It may occur either at the
beginning or the end of a glaciation,
although an overturn at the start of a glaciation is more dangerous
because the preceding warm period will have created a larger volume of
anoxic water.
Unlike other oceanic catastrophes such as regressions (sea-level
falls) and anoxic events, overturns do not leave easily identified
"signatures" in rocks and are theoretical consequences of researchers'
conclusions about other climatic and marine events.
It has been suggested that oceanic overturn caused or contributed to the late Devonian and Permian–Triassic extinctions.
A nearby nova, supernova or gamma ray burst
A nearby gamma-ray burst (less than 6000 light-years away) would be powerful enough to destroy the Earth's ozone layer, leaving organisms vulnerable to ultraviolet radiation from the Sun. Gamma ray bursts are fairly rare, occurring only a few times in a given galaxy per million years.
It has been suggested that a supernova or gamma ray burst caused the End-Ordovician extinction.
Geomagnetic reversal
One theory is that periods of increased geomagnetic reversals will weaken Earth's magnetic field long enough to expose the atmosphere to the solar winds, causing oxygen ions to escape the atmosphere in a rate increased by 3–4 orders, resulting in a disastrous decrease in oxygen.
Plate tectonics
Movement
of the continents into some configurations can cause or contribute to
extinctions in several ways: by initiating or ending ice ages;
by changing ocean and wind currents and thus altering climate; by
opening seaways or land bridges which expose previously isolated species
to competition for which they are poorly adapted (for example, the
extinction of most of South America's native ungulates and all of its large metatherians after the creation of a land bridge between North and South America).
Occasionally continental drift creates a super-continent which includes
the vast majority of Earth's land area, which in addition to the
effects listed above is likely to reduce the total area of continental shelf
(the most species-rich part of the ocean) and produce a vast, arid
continental interior which may have extreme seasonal variations.
Another theory is that the creation of the super-continent Pangaea contributed to the End-Permian
mass extinction. Pangaea was almost fully formed at the transition from
mid-Permian to late-Permian, and the "Marine genus diversity" diagram
at the top of this article shows a level of extinction starting at that
time which might have qualified for inclusion in the "Big Five" if it
were not overshadowed by the "Great Dying" at the end of the Permian.
Other hypotheses
Many
other hypotheses have been proposed, such as the spread of a new
disease, or simple out-competition following an especially successful
biological innovation. But all have been rejected, usually for one of
the following reasons: they require events or processes for which there
is no evidence; they assume mechanisms which are contrary to the
available evidence; they are based on other theories which have been
rejected or superseded.
Scientists have been concerned that human activities could cause
more plants and animals to become extinct than any point in the past.
Along with human-made changes in climate (see above), some of these
extinctions could be caused by overhunting, overfishing, invasive
species, or habitat loss. A study published in May 2017 in Proceedings of the National Academy of Sciences
argued that a “biological annihilation” akin to a sixth mass extinction
event is underway as a result of anthropogenic causes, such as over-population and over-consumption.
The study suggested that as much as 50% of the number of animal
individuals that once lived on Earth were already extinct, threatening
the basis for human existence too.
Future biosphere extinction/sterilization
The eventual warming and expanding of the Sun, combined with the
eventual decline of atmospheric carbon dioxide could actually cause an
even greater mass extinction, having the potential to wipe out even
microbes (in other words, the Earth is completely sterilized), where
rising global temperatures caused by the expanding Sun will gradually
increase the rate of weathering, which in turn removes more and more
carbon dioxide from the atmosphere. When carbon dioxide levels get too
low (perhaps at 50 ppm), all plant life will die out, although simpler
plants like grasses and mosses can survive much longer, until CO
2 levels drop to 10 ppm.
2 levels drop to 10 ppm.
With all photosynthetic organisms gone, atmospheric oxygen can no
longer be replenished, and is eventually removed by chemical reactions
in the atmosphere, perhaps from volcanic eruptions. Eventually the loss
of oxygen will cause all remaining aerobic life to die out via
asphyxiation, leaving behind only simple anaerobic prokaryotes. When the
Sun becomes 10% brighter in about a billion years,
Earth will suffer a moist greenhouse effect resulting in its oceans
boiling away, while the Earth's liquid outer core cools due to the inner
core's expansion and causes the Earth's magnetic field to shut down. In
the absence of a magnetic field, charged particles from the Sun will
deplete the atmosphere and further increase the Earth's temperature to
an average of ~420 K (147 °C, 296 °F) in 2.8 billion years, causing the
last remaining life on Earth to die out. This is the most extreme
instance of a climate-caused extinction event. Since this will only
happen late in the Sun's life, such will cause the final mass extinction
in Earth's history (albeit a very long extinction event).
Effects and recovery
The impact of mass extinction events varied widely. After a major extinction event, usually only weedy species survive due to their ability to live in diverse habitats. Later, species diversify and occupy empty niches. Generally, biodiversity
recovers 5 to 10 million years after the extinction event. In the most
severe mass extinctions it may take 15 to 30 million years.
The worst event, the Permian–Triassic extinction,
devastated life on earth, killing over 90% of species. Life seemed to
recover quickly after the P-T extinction, but this was mostly in the
form of disaster taxa, such as the hardy Lystrosaurus.
The most recent research indicates that the specialized animals that
formed complex ecosystems, with high biodiversity, complex food webs and
a variety of niches, took much longer to recover. It is thought that
this long recovery was due to successive waves of extinction which
inhibited recovery, as well as prolonged environmental stress which
continued into the Early Triassic. Recent research indicates that
recovery did not begin until the start of the mid-Triassic, 4M to 6M
years after the extinction;
and some writers estimate that the recovery was not complete until 30M
years after the P-T extinction, i.e. in the late Triassic.
Subsequent to the P-T extinction, there was an increase in
provincialization, with species occupying smaller ranges – perhaps
removing incumbents from niches and setting the stage for an eventual
rediversification.
The effects of mass extinctions on plants are somewhat harder to
quantify, given the biases inherent in the plant fossil record. Some
mass extinctions (such as the end-Permian) were equally catastrophic for
plants, whereas others, such as the end-Devonian, did not affect the
flora.