This timeline of evolution of life outlines the major
events in the development of life on planet Earth since it originated
until the present day. In biology, evolution is any change across successive generations in the
heritable characteristics of biological populations. Evolutionary processes
give rise to diversity at every level of biological organization, from kingdoms
to species,
and individual organisms and molecules such as DNA and proteins. The
similarities between all present day organisms indicate the presence of a common
ancestor from which all known species, living and extinct, have
diverged through the process of evolution.
The dates given in this article are estimates based on
scientific evidence.
Basic timeline
The basic timeline of a 4.6 billion
year old Earth, with approximate dates:
- 3.8 billion years of simple
cells (prokaryotes),
- 3.4 billion years of stromatolites
demonstrating photosynthesis,
- 2 billion years of complex cells (eukaryotes),
- 1 billion years of multicellular life,
- 600 million years of simple animals,
- 570 million years of arthropods (ancestors of insects,
arachnids and crustaceans),
- 550 million years of complex animals,
- 500 million years of fish and proto-amphibians,
- 475 million years of land plants,
- 400 million years of insects and seeds,
- 360 million years of amphibians,
- 300 million years of reptiles,
- 200 million years of mammals,
- 150 million years of birds,
- 130 million years of flowers,
- 65 million years since the dinosaurs
died out,
- 2.5 million years since the appearance of the genus Homo,
- 200,000 years of anatomically modern humans,
- 25,000 years since the disappearance of Neanderthal
traits from the fossil record.
- 13,000 years since the disappearance of Homo floresiensis from the fossil
record.
Detailed timeline
Ma,
("megaannum") means "million years ago". ka means
"thousand years ago" and ya means "years ago"
Hadean Eon
Main article: Hadean
3800 Ma and earlier.
|
Date
|
Event
|
|
4600 Ma
|
The planet Earth forms from the accretion
disc revolving around the young Sun; complex
organic molecules necessary for life may have formed in
the protoplanetary disk of dust grains
surrounding the Sun
before the formation of the Earth.[1]
|
|
4500 Ma
|
According to the giant impact hypothesis the moon is
formed when the planet Earth and the planet Theia
collide, sending a very large number of moonlets into orbit around the young
Earth which eventually coalesce to form the Moon.[2]
The gravitational pull of the new Moon stabilises the Earth's fluctuating axis of
rotation and sets up the conditions in which life formed.[3]
|
|
4100 Ma
|
The surface of the Earth cools enough for the crust
to solidify. The atmosphere and the oceans form.[4]
PAH infall,[5]
and iron sulfide synthesis along deep ocean
platelet boundaries, may have led to the RNA world
of competing organic compounds.
|
|
4500-3500 Ma
|
The earliest life appears, possibly derived from self-reproducing RNA molecules.[6][7]
The replication of these organisms requires resources like energy, space, and
smaller building blocks, which soon become limited, resulting in competition,
with natural selection favouring those molecules
which are more efficient at replication. DNA molecules then take
over as the main replicators and these archaic genomes
soon develop inside enclosing membranes which provide a stable physical and
chemical environment conducive to their replication: proto-cells.[8][9][10]
|
|
3900 Ma
|
Late Heavy Bombardment: peak rate of impact
events upon the inner planets by meteoroids. This constant disturbance may have obliterated any life
that had evolved to that point, or possibly not, as some early microbes
could have survived in hydrothermal vents below the Earth's
surface;[11]
or life might have been transported to Earth by a meteoroid.[12]
|
|
3900-2500 Ma
|
Cells resembling prokaryotes
appear.[13]
These first organisms are chemoautotrophs: they use carbon
dioxide as a carbon source and oxidize
inorganic materials to extract energy. Later, prokaryotes evolve glycolysis,
a set of chemical reactions that free the energy of organic molecules such as
glucose
and store it in the chemical bonds of ATP. Glycolysis (and ATP) continue to be
used in almost all organisms, unchanged, to this day.[14][15]
|
Archean Eon
Main article: Archean
3800 Ma – 2500 Ma
|
Date
|
Event
|
|
3500 Ma
|
Bacteria
develop primitive forms of photosynthesis
which at first do not produce oxygen.[19]
These organisms generate ATP by exploiting a proton gradient, a mechanism still used
in virtually all organisms.
|
|
3000 Ma
|
Photosynthesizing cyanobacteria
evolve; they use water as a reducing
agent, thereby producing oxygen as waste product.[20]
The oxygen initially oxidizes dissolved iron in the oceans, creating iron ore.
The oxygen concentration in the atmosphere slowly rises, acting as a poison
for many bacteria. The Moon is still very close to Earth and causes tides 1,000 feet
(305 m) high. The Earth is continually wracked by hurricane-force
winds. These extreme mixing influences are thought to stimulate evolutionary
processes. (See Oxygen catastrophe).
|
Proterozoic Eon
Main article: Proterozoic
2500 Ma – 542 Ma
|
Date
|
Event
|
|
2500 Ma
|
|
|
2000 Ma
|
|
|
By 1850 Ma
|
Eukaryotic cells appear. Eukaryotes contain
membrane-bound organelles with diverse functions, probably
derived from prokaryotes engulfing each other via phagocytosis.
(See Endosymbiosis).[22][23]
|
|
1400 Ma
|
Great increase in stromatolite
diversity.
|
|
By 1200 Ma
|
|
|
1200 Ma
|
Simple multicellular organisms evolve, mostly
consisting of cell colonies of limited complexity. First multicellular red algae
evolve
|
|
1100 Ma
|
Earliest dinoflagellates
|
|
1000 Ma
|
|
|
750 Ma
|
|
|
850–630 Ma
|
|
|
580–542 Ma
|
The Ediacaran biota represent the first large,
complex multicellular organisms - although their affinities remain a subject
of debate.[30]
|
|
580–500 Ma
|
Most modern phyla of animals begin to appear in the fossil record during
the Cambrian explosion.[31][32]
|
|
580–540 Ma
|
The accumulation of atmospheric oxygen allows the
formation of an ozone layer.[33]
This blocks ultraviolet radiation, permitting the
colonisation of the land.[33]
|
|
560 Ma
|
Earliest fungi
|
|
550 Ma
|
First fossil evidence for ctenophora
(comb-jellies), porifera (sponges), and anthozoa
(corals
& anemones)
|
Phanerozoic Eon
Main article: Phanerozoic
542 Ma – present
The Phanerozoic Eon, literally the "period of
well-displayed life", marks the appearance in the fossil record of
abundant, shell-forming and/or trace-making organisms. It is subdivided into
three eras, the Paleozoic, Mesozoic and Cenozoic, which are divided by major mass
extinctions.
Paleozoic Era
542 Ma – 251.0 Ma
|
Date
|
Event
|
|
535 Ma
|
Major diversification of living things in the oceans: chordates,
arthropods
(e.g. trilobites,
crustaceans),
echinoderms,
mollusks,
brachiopods,
foraminifers
and radiolarians,
etc.
|
|
530 Ma
|
The first known footprints on land date to 530 Ma,
indicating that early animal explorations may have predated the development
of terrestrial plants.[34]
|
|
525 Ma
|
Earliest graptolites.
|
|
510 Ma
|
|
|
505 Ma
|
Fossilization of the Burgess
Shale.
|
|
485 Ma
|
First vertebrates with true bones (jawless
fishes).
|
|
450 Ma
|
|
|
440 Ma
|
|
|
434 Ma
|
|
|
420 Ma
|
|
|
410 Ma
|
|
|
395 Ma
|
First lichens, stoneworts. Earliest harvestman,
mites,
hexapods
(springtails)
and ammonoids.
The first known tetrapod tracks on land.
|
|
363 Ma
|
By the start of the Carboniferous
Period, the Earth begins to be recognisable. Insects
roamed the land and would soon take to the skies; sharks swam
the oceans as top predators,[37]
and vegetation covered the land, with seed-bearing plants and forests soon to
flourish.
Four-limbed
tetrapods
gradually gain adaptations which will help them occupy a terrestrial
life-habit.
|
|
360 Ma
|
|
|
350 Ma
|
|
|
340 Ma
|
Diversification of amphibians.
|
|
330 Ma
|
|
|
320 Ma
|
|
|
305 Ma
|
|
|
280 Ma
|
Earliest beetles, seed plants and conifers diversify while lepidodendrids
and sphenopsids
decrease. Terrestrial temnospondyl amphibians and pelycosaurs (e.g. Dimetrodon)
diversify in species.
|
|
275 Ma
|
|
|
251.4 Ma
|
The Permian-Triassic extinction event
eliminates over 90-95% of marine species. Terrestrial organisms were not as
seriously affected as the marine biota. This "clearing of the
slate" may have led to an ensuing diversification, but life on land took
30M years to completely recover.[39]
|
Mesozoic Era
Main article: Mesozoic
|
Date
|
Event
|
|
From 251.4 Ma
|
The Mesozoic Marine Revolution begins: increasingly
well-adapted and diverse predators pressurize sessile marine groups; the
"balance of power" in the oceans shifts dramatically as some groups
of prey adapt more rapidly and effectively than others.
|
|
245 Ma
|
Earliest ichthyosaurs.
|
|
240 Ma
|
|
|
225 Ma
|
Earliest dinosaurs (prosauropods),
first cardiid bivalves, diversity in cycads,
bennettitaleans, and conifers. First teleost
fishes. First mammals
(Adelobasileus).
|
|
220 Ma
|
Gymnosperm forests dominate the land;
herbivores grow to huge sizes in order to accommodate the large guts
necessary to digest the nutrient-poor plants.[citation needed], first flies and turtles
(Odontochelys).
First Coelophysoid dinosaurs
|
|
200 Ma
|
The first accepted evidence for viruses (at
least, the group Geminiviridae) exists.[40]
Viruses are still poorly understood and may have arisen before
"life" itself, or may be a more recent phenomenon.
Major
extinctions in terrestrial vertebrates and large amphibians. Earliest
examples of Ankylosaurian dinosaurs
|
|
195 Ma
|
First pterosaurs with specialized feeding (Dorygnathus).
First sauropod
dinosaurs. Diversification in small, ornithischian
dinosaurs: heterodontosaurids, fabrosaurids,
and scelidosaurids.
|
|
190 Ma
|
Pliosaurs appear in the fossil record. First lepidopteran
insects (Archaeolepis), hermit
crabs, modern starfish, irregular echinoids,
corbulid
bivalves, and tubulipore bryozoans. Extensive development of sponge
reefs.
|
|
176 Ma
|
First members of the Stegosauria
group of dinosaurs
|
|
170 Ma
|
Earliest salamanders, newts, cryptoclidid
& elasmosaurid plesiosaurs, and cladotherian
mammals. Sauropod dinosaurs diversify.
|
|
165 Ma
|
|
|
161 Ma
|
|
|
155 Ma
|
First blood-sucking insects (ceratopogonids),
rudist
bivalves, and cheilostome bryozoans. Archaeopteryx,
a possible ancestor to the birds, appears in the fossil record, along with triconodontid
and symmetrodont
mammals. Diversity in stegosaurian and theropod
dinosaurs.
|
|
130 Ma
|
The rise of the Angiosperms:
These flowering
plants boast structures that attract insects and other animals to spread pollen.
This innovation causes a major burst of animal evolution through co-evolution.
First freshwater pelomedusid turtles.
|
|
120 Ma
|
|
|
115 Ma
|
First monotreme mammals.
|
|
110 Ma
|
First hesperornithes, toothed diving birds.
Earliest limopsid,
verticordiid,
and thyasirid
bivalves.
|
|
106 Ma
|
Spinosaurus, the largest theropod dinosaur, appears in the fossil
record.
|
|
100 Ma
|
Earliest bees.
|
|
90 Ma
|
Extinction of ichthyosaurs.
Earliest snakes
and nuculanid
bivalves. Large diversification in angiosperms: magnoliids,
rosids,
hamamelidids,
monocots,
and ginger.
Earliest examples of ticks.
|
|
80 Ma
|
First ants.
|
|
70 Ma
|
|
|
68 Ma
|
Tyrannosaurus, the largest terrestrial
predator of
|
Cenozoic Era
Main article: Cenozoic
65.5 Ma – present
|
Date
|
Event
|
|
65.5 Ma
|
The Cretaceous–Paleogene extinction
event eradicates about half of all animal species, including mosasaurs,
pterosaurs,
plesiosaurs,
ammonites,
belemnites,
rudist and inoceramid bivalves, most planktic foraminifers, and all of the
dinosaurs excluding their descendants the birds [41]
|
|
From 65 Ma
|
Rapid dominance of conifers
and ginkgos
in high latitudes, along with mammals becoming the dominant species. First psammobiid
bivalves. Rapid diversification in ants.
|
|
63 Ma
|
Evolution of the creodonts,
an important group of carnivorous mammals.
|
|
60 Ma
|
Diversification of large, flightless
birds. Earliest true primates,
along with the first semelid bivalves, edentates,
carnivorous
and lipotyphlan
mammals, and owls.
The ancestors of the carnivorous mammals (miacids)
were alive.
|
|
56 Ma
|
Gastornis, a large, flightless bird appears in the fossil record,
becoming an apex predator at the time.
|
|
55 Ma
|
Modern bird groups diversify (first song birds,
parrots,
loons,
swifts,
woodpeckers),
first whale (Himalayacetus), earliest rodents,
lagomorphs,
armadillos,
appearance of sirenians, proboscideans,
perissodactyl
and artiodactyl
mammals in the fossil record. Angiosperms diversify. The ancestor (according
to theory) of the species in Carcharodon,
the early mako shark
Isurus hastalis, is alive.
|
|
52 Ma
|
|
|
50 Ma
|
Peak diversity of dinoflagellates and nanofossils,
increase in diversity of anomalodesmatan and heteroconch bivalves, brontotheres,
tapirs,
rhinoceroses,
and camels
appear in the fossil record, diversification of primates.
|
|
40 Ma
|
Modern-type butterflies
and moths
appear. Extinction of Gastornis. Basilosaurus,
one of the first of the giant whales, appeared in the fossil record.
|
|
37 Ma
|
First Nimravid carnivores ("False
Saber-toothed Cats") - these species are unrelated to modern-type
felines
|
|
35 Ma
|
Grasses evolve from among the angiosperms;
grasslands begin to expand. Slight increase in diversity of cold-tolerant ostracods
and foraminifers, along with major extinctions of gastropods,
reptiles,
and amphibians.
Many modern mammal groups begin to appear: first glyptodonts,
ground
sloths, dogs,
peccaries,
and the first eagles
and hawks.
Diversity in toothed and baleen
whales.
|
|
33 Ma
|
|
|
30 Ma
|
|
|
28 Ma
|
Paraceratherium appears in the fossil record,
the largest terrestrial mammal that ever lived.
|
|
25 Ma
|
First deer.
|
|
20 Ma
|
|
|
15 Ma
|
|
|
10 Ma
|
|
|
6.5 Ma
|
First hominin (Sahelanthropus).
|
|
6 Ma
|
|
|
5 Ma
|
First tree sloths and hippopotami,
diversification of grazing herbivores like zebras
and elephants,
large carnivorous mammals like lions and dogs, burrowing rodents, kangaroos, birds, and small
carnivores, vultures
increase in size, decrease in the number of perissodactyl mammals. Extinction
of Nimravid
carnivores
|
|
4.8 Ma
|
Mammoths appear in the fossil record.
|
|
4 Ma
|
Evolution of Australopithecus,
Stupendemys
appears in the fossil record as the largest freshwater turtle, first modern elephants,
giraffes,
zebras,
lions,
rhinos
and gazelles
appear in the fossil record.
|
|
3 Ma
|
The Great American Interchange, where
various land and freshwater faunas migrated between North and
|
|
2.7 Ma
|
Evolution of Paranthropus
|
|
2.5 Ma
|
The earliest species of Smilodon
evolve
|
|
2 Ma
|
First members of the genus Homo
appear in the fossil record. Diversification of conifers in high latitudes.
The eventual ancestor of cattle, Bos
primigenius evolves in
|
|
1.7 Ma
|
Extinction of australopithecines.
|
|
1.2 Ma
|
|
|
600 ka
|
Evolution of Homo heidelbergensis
|
|
350 ka
|
Evolution of Neanderthals
|
|
300 ka
|
|
|
200 ka
|
Anatomically modern humans appear in
|
|
40 ka
|
The last of the giant monitor lizards (Megalania)
die out
|
|
30 ka
|
|
|
15 ka
|
The last Woolly rhinoceros (Coelodonta) are
believed to have gone extinct
|
|
11 ka
|
The giant short-faced bears (Arctodus)
vanish from
|
|
10 ka
|
The Holocene Epoch starts 10,000[45]
years ago after the Late Glacial Maximum. The last mainland
species of Woolly mammoth (Mammuthus primigenius)
die out, as does the last Smilodon species
|
|
6 ka
|
|
|
4500 ya
|
|
|
385 ya (1627)
|
The last recorded wild Aurochs
die out
|
|
76 ya (1936)
|
The Thylacine goes extinct in a Tasmanian zoo,
the last member of the family Thylacinidae
|
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