The timeline of human evolution outlines the major events in the evolutionary lineage of the modern human species, Homo sapiens, throughout the history of life, beginning some 4 billion years ago down to recent evolution within H. sapiens during and since the Last Glacial Period.
It includes brief explanations of the various taxonomic ranks in the human lineage. The timeline reflects the mainstream views in modern taxonomy, based on the principle of phylogenetic nomenclature;in cases of open questions with no clear consensus, the main competing possibilities are briefly outlined.
A tabular overview of the taxonomic ranking of Homo sapiens (with age estimates for each rank) is shown below.
Rank | Name | Common name | Millions of years ago (commencement) |
---|---|---|---|
Life | 4,200 | ||
Archaea | 3,700 | ||
Domain | Eukaryota | Eukaryotes | 2,100 |
Opimoda | Excludes Plants and their relatives | 1,540 | |
Amorphea | |||
Obazoa | Excludes Amoebozoa (Amoebas) | ||
Opisthokonts | Holozoa + Holomycota (Cristidicoidea and Fungi) | 1,300 | |
Holozoa | Excludes Holomycota | 1,100 | |
Filozoa | Choanozoa + Filasterea | ||
Choanozoa | Choanoflagellates + Animals | 900 | |
Kingdom | Animalia | Animals | 610 |
Subkingdom | Eumetazoa | Excludes Porifera (Sponges) | |
Parahoxozoa | Excludes Ctenophora (Comb Jellies) | ||
Bilateria | Triploblasts / Worms | 560 | |
Nephrozoa | |||
Deuterostomes | Division from Protostomes | ||
Phylum | Chordata | Chordates (Vertebrates and closely related invertebrates) | 530 |
Olfactores | Excludes cephalochordates (Lancelets) | ||
Subphylum | Vertebrata | Fish / Vertebrates | 505 |
Infraphylum | Gnathostomata | Jawed fish | 460 |
Teleostomi | Bony fish | 420 | |
Sarcopterygii | Lobe finned fish | ||
Superclass | Tetrapoda | Tetrapods (animals with four limbs) | 395 |
Amniota | Amniotes (fully terrestrial tetrapods whose eggs are "equipped with an amnion") | 340 | |
Synapsida | Proto-Mammals | 308 | |
Therapsid | Limbs beneath the body and other mammalian traits | 280 | |
Class | Mammalia | Mammals | 220 |
Subclass | Theria | Mammals that give birth to live young (i.e., non-egg-laying) | 160 |
Infraclass | Eutheria | Placental mammals (i.e., non-marsupials) | 125 |
Magnorder | Boreoeutheria | Supraprimates, (most) hoofed mammals, (most) carnivorous mammals, cetaceans, and bats | 124–101 |
Superorder | Euarchontoglires | Supraprimates: primates, colugos, tree shrews, rodents, and rabbits | 100 |
Grandorder | Euarchonta | 99–80 | |
Mirorder | Primatomorpha | Primates and colugos | 79.6 |
Order | Primates | Primates / Plesiadapiformes | 66 |
Suborder | Haplorrhini | "Dry-nosed" (literally, "simple-nosed") primates: tarsiers and monkeys (incl. apes) | 63 |
Infraorder | Simiiformes | monkeys (incl. apes) | 40 |
Parvorder | Catarrhini | "Downward-nosed" primates: apes and old-world monkeys | 30 |
Superfamily | Hominoidea | Apes: great apes and lesser apes (gibbons) | 22-20 |
Family | Hominidae | Great apes: humans, chimpanzees, gorillas and orangutans—the hominids | 20–15 |
Subfamily | Homininae | Humans, chimpanzees, and gorillas (the African apes)[1] | 14–12 |
Tribe | Hominini | Includes both Homo, Pan (chimpanzees), but not Gorilla. | 10–8 |
Subtribe | Hominina | Genus Homo and close human relatives and ancestors after splitting from Pan—the hominins | 8–4[2] |
(Genus) | Ardipithecus s.l. | 6-4 | |
(Genus) | Australopithecus | 3 | |
Genus | Homo (H. habilis) | Humans | 2.5 |
(Species) | H. erectus s.l. | ||
(Species) | H. heidelbergensis s.l. | ||
Species | Anatomically modern humans | 0.8–0.3[3] | |
Date | Event |
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4.3-4.1 Ga | The earliest life appears, possibly as protocells. Their genetic material was probably composed of RNA, capable of both self replication and enzymatic activity; their membranes were composed of lipids. The genes were separate strands, translated into proteins and often exchanged between the protocells. |
4.0-3.8 Ga | Prokaryotic cells appear; their genetic materials are composed of the more stable DNA and they use proteins for various reasons, primarily for aiding DNA to replicate itself by proteinaceous enzymes (RNA now acts as an intermediary in this central dogma of genetic information flow of cellular life); genes are now linked in sequences so all information passes to offsprings. They had cell walls & outer membranes and were probably initially thermophiles. |
3.5 Ga | This marks the first appearance of cyanobacteria and their method of oxygenic photosynthesis and therefore the first occurrence of atmospheric oxygen on Earth. For another billion years, prokaryotes would continue to diversify undisturbed. |
2.5-2.2 Ga | First organisms to use oxygen. By 2400 Ma, in what is referred to as the Great Oxidation Event, (GOE), most of the pre-oxygen anaerobic forms of life were wiped out by the oxygen producers. |
2.2-1.8 Ga | Origin of the eukaryotes: organisms with nuclei, endomembrane systems (including mitochondria) and complex cytoskeletons; they spliced mRNA between transcription and translation (splicing also occurs in prokaryotes, but it is only of non-coding RNAs). The evolution of eukaryotes, and possibly sex, is thought to be related to the GOE, as it probably pressured two or three lineages of prokaryotes (including an aerobe one, which later became mitochondria) to depend on each other, leading to endosymbiosis. Early eukaryotes lost their cell walls and outer membranes. |
1.2 Ga | Sexual reproduction evolves (mitosis and meiosis) by this time at least, leading to faster evolution[4] where genes are mixed in every generation enabling greater variation for subsequent selection. |
1.2-0.8 Ga | The Holozoa lineage of eukaryotes evolves many features for making cell colonies, and finally leads to the ancestor of animals (metazoans) and choanoflagellates.[5] [6] Proterospongia (members of the Choanoflagellata) are the best living examples of what the ancestor of all animals may have looked like. They live in colonies, and show a primitive level of cellular specialization for different tasks. |
Date | Event | |
---|---|---|
800–650 Ma | Urmetazoan The first fossils that might represent animals appear in the 665-million-year-old rocks of the Trezona Formation of South Australia. These fossils are interpreted as being early sponges.[7] Multicellular animals may have existed from 800 Ma. Separation from the Porifera (sponges) lineage.Eumetazoa/Diploblast: separation from the Ctenophora ("comb jellies") lineage.Planulozoa/ParaHoxozoa: separation from the Placozoa and Cnidaria lineages.All diploblasts possess epithelia, nerves, muscles and connective tissue and mouths, and except for placozoans, have some form of symmetry, with their ancestors probably having radial symmetry like that of cnidarians. Diploblasts separated their early embryonic cells into two germ layers (ecto- and endoderm). Photoreceptive eye-spots evolve. | |
650-600 Ma | Urbilaterian the last common ancestor of xenacoelomorphs, protostomes (including the arthropod [insect, crustacean, spider], mollusc [squid, snail, clam] and annelid [earthworm] lineages) and the deuterostomes (including the vertebrate [human] lineage) (the last two are more related to each other and called Nephrozoa). Xenacoelomorphs all have a gonopore to expel gametes but nephrozoans merged it with their anus. Earliest development of bilateral symmetry, mesoderm, head (anterior cephalization) and various gut muscles (and thus peristalsis) and, in the Nephrozoa, nephridia (kidney precursors), coelom (or maybe pseudocoelom), distinct mouth and anus (evolution of through-gut), and possibly even nerve cords and blood vessels.[8] Reproductive tissue probably concentrates into a pair of gonads connecting just before the posterior orifice. "Cup-eyes" and balance organs evolve (the function of hearing added later as the more complex inner ear evolves in vertebrates). The nephrozoan through-gut had a wider portion in the front, called the pharynx. The integument or skin consists of an epithelial layer (epidermis) and a connective layer. | |
600-540 Ma | Most known animal phyla appeared in the fossil record as marine species during the Ediacaran-Cambrian explosion, probably caused by long scale oxygenation since around 585 Ma (sometimes called the Neoproterozoic Oxygenation Event or NOE) and also an influx of oceanic minerals. Deuterostomes, the last common ancestor of the Chordata [human] lineage, Hemichordata (acorn worms and graptolites) and Echinodermata (starfish, sea urchins, sea cucumbers, etc.), probably had both ventral and dorsal nerve cords like modern acorn worms. An archaic survivor from this stage is the acorn worm, sporting an open circulatory system (with less branched blood vessels) with a heart that also functions as a kidney. Acorn worms have a plexus concentrated into both dorsal and ventral nerve cords. The dorsal cord reaches into the proboscis, and is partially separated from the epidermis in that region. This part of the dorsal nerve cord is often hollow, and may well be homologous with the brain of vertebrates.[9] Deuterostomes also evolved pharyngeal slits, which were probably used for filter feeding like in hemi- and proto-chordates. |
Date | Event | |
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300-260 Ma | Shortly after the appearance of the first reptiles, two branches split off. One branch is the Sauropsida, from which come the modern reptiles and birds. The other branch is Synapsida from which come modern mammals. Both had temporal fenestrae, a pair of holes in their skulls behind the eyes, which were used to increase the space for jaw muscles. Synapsids had one opening on each side, while diapsids (a branch of Sauropsida) had two. An early, inefficient version of diaphragm may have evolved in synapsids. The earliest "mammal-like reptiles" are the pelycosaurs. The pelycosaurs were the first animals to have temporal fenestrae. Pelycosaurs were not therapsids but their ancestors. The therapsids were, in turn, the ancestors of mammals. The therapsids had temporal fenestrae larger and more mammal-like than pelycosaurs, their teeth showed more serial differentiation, their gait was semi-erect and later forms had evolved a secondary palate. A secondary palate enables the animal to eat and breathe at the same time and is a sign of a more active, perhaps warm-blooded, way of life.[21] They had lost gastralia and, possibly, scales. | |
260-230 Ma | One subgroup of therapsids, the cynodonts, lose pineal eye & lumbar ribs and very likely became warm-blooded. The lower respiratory tract forms intricate branches in the lung parenchyma, ending in highly vascularized alveoli. Erythrocytes and thrombocytes lose their nuclei while lymphatic systems and advanced immunity emerge. They may have also had thicker dermis like mammals today. The jaws of cynodonts resembled modern mammal jaws; the anterior portion, the dentary, held differentiated teeth. This group of animals likely contains a species which is the ancestor of all modern mammals. Their temporal fenestrae merged with their orbits. Their hindlimbs became erect and their posterior bones of the jaw progressively shrunk to the region of the columella.[22] | |
230-170 Ma | From Eucynodontia came the first mammals. Most early mammals were small shrew-like animals that fed on insects and had transitioned to nocturnality to avoid competition with the dominant archosaurs — this led to the loss of the vision of red and ultraviolet light (ancestral tetrachromacy of vertebrates reduced to dichromacy). Although there is no evidence in the fossil record, it is likely that these animals had a constant body temperature, hair and milk glands for their young (the glands stemmed from the milk line). The neocortex (part of the cerebrum) region of the brain evolves in Mammalia, at the reduction of the tectum (non-smell senses which were processed here became integrated into neocortex but smell became primary sense). Origin of the prostate gland and a pair of holes opening to the columella and nearby shrinking jaw bones; new eardrums stand in front of the columella and Eustachian tube. The skin becomes hairy, glandular (glands secreting sebum and sweat) and thermoregulatory. Teeth fully differentiate into incisors, canines, premolars and molars; mammals become diphyodont and possess developed diaphragms and males have internal penises. All mammals have four chambered hearts (with two atria and two ventricles) and lack cervical ribs (now mammals only have thoracic ribs). Monotremes are an egg-laying group of mammals represented today by the platypus and echidna. Recent genome sequencing of the platypus indicates that its sex genes are closer to those of birds than to those of the therian (live birthing) mammals. Comparing this to other mammals, it can be inferred that the first mammals to gain sexual differentiation through the existence or lack of SRY gene (found in the y-Chromosome) evolved only in the therians. Early mammals and possibly their eucynodontian ancestors had epipubic bones, which serve to hold the pouch in modern marsupials (in both sexes). | |
170-120 Ma | Evolution of live birth (viviparity), with early therians probably having pouches for keeping their undeveloped young like in modern marsupials. Nipples stemmed out of the therian milk lines. The posterior orifice separates into anal and urogenital openings; males possess an external penis. Monotremes and therians independently detach the malleus and incus from the dentary (lower jaw) and combine them to the shrunken columella (now called stapes) in the tympanic cavity behind the eardrum (which is connected to the malleus and held by another bone detached from the dentary, the tympanic plus ectotympanic), and coil their lagena (cochlea) to advance their hearing, with therians further evolving an external pinna and erect forelimbs. Female placentalian mammals do not have pouches and epipubic bones but instead have a developed placenta which penetrates the uterus walls (unlike marsupials), allowing a longer gestation; they also have separated urinary and genital openings.[23] | |
100-90 Ma | Last common ancestor of rodents, rabbits, ungulates, carnivorans, bats, shrews and humans (base of the clade Boreoeutheria; males now have external testicles). |
Date | Event | |
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90–66 Ma | A group of small, nocturnal, arboreal, insect-eating mammals called Euarchonta begins a speciation that will lead to the orders of primates, treeshrews and flying lemurs. They reduced the number of mammaries to only two pairs (on the chest). Primatomorpha is a subdivision of Euarchonta including primates and their ancestral stem-primates Plesiadapiformes. An early stem-primate, Plesiadapis, still had claws and eyes on the side of the head, making it faster on the ground than in the trees, but it began to spend long times on lower branches, feeding on fruits and leaves. The Plesiadapiformes very likely contain the ancestor species of all primates.[24] They first appeared in the fossil record around 66 million years ago, soon after the Cretaceous–Paleogene extinction event that eliminated about three-quarters of plant and animal species on Earth, including most dinosaurs.[25] [26] One of the last Plesiadapiformes is Carpolestes simpsoni, having grasping digits but not forward-facing eyes. | |
66-56 Ma | Primates diverge into suborders Strepsirrhini (wet-nosed primates) and Haplorrhini (dry-nosed primates). Brain expands and cerebrum divides into 4 pairs of lobes. The postorbital bar evolves to separate the orbit from the temporal fossae as sight regains its position as the primary sense; eyes became forward-facing. Strepsirrhini contain most prosimians; modern examples include lemurs and lorises. The haplorrhines include the two living groups: prosimian tarsiers, and simian monkeys, including apes. The Haplorrhini metabolism lost the ability to produce vitamin C, forcing all descendants to include vitamin C-containing fruit in their diet. Early primates only had claws in their second digits; the rest were turned into nails. | |
50-35 Ma | Simians split into infraorders Platyrrhini and Catarrhini. They fully transitioned to diurnality and lacked any claw and tapetum lucidum (which evolved many times in various vertebrates). They possibly evolved at least some of the paranasal sinuses, and transitioned from estrous cycle to menstrual cycle. The number of mammaries is now reduced to only one thoracic pair. Platyrrhines, New World monkeys, have prehensile tails and males are color blind. The individuals whose descendants would become Platyrrhini are conjectured to have migrated to South America either on a raft of vegetation or via a land bridge (the hypothesis now favored[27]). Catarrhines mostly stayed in Africa as the two continents drifted apart. Possible early ancestors of catarrhines include Aegyptopithecus and Saadanius. | |
35-20 Ma | Catarrhini splits into 2 superfamilies, Old World monkeys (Cercopithecoidea) and apes (Hominoidea). Human trichromatic color vision had its genetic origins in this period. Catarrhines lost the vomeronasal organ (or possibly reduced it to vestigial status). Proconsul was an early genus of catarrhine primates. They had a mixture of Old World monkey and ape characteristics. Proconsuls monkey-like features include thin tooth enamel, a light build with a narrow chest and short forelimbs, and an arboreal quadrupedal lifestyle. Its ape-like features are its lack of a tail, ape-like elbows, and a slightly larger brain relative to body size. Proconsul africanus is a possible ancestor of both great and lesser apes, including humans. |
Date | Event | |
---|---|---|
20-15 Ma | Hominidae (great ape ancestors) speciate from the ancestors of the gibbon (lesser apes) between c. 20 to 16 Ma. They largely reduced their ancestral snout and lost the uricase enzyme (present in most organisms).[28] | |
16-12 Ma | Homininae ancestors speciate from the ancestors of the orangutan between c. 18 to 14 Ma.[29] Pierolapithecus catalaunicus is thought to be a common ancestor of humans and the other great apes, or at least a species that brings us closer to a common ancestor than any previous fossil discovery. It had the special adaptations for tree climbing as do present-day humans and other great apes: a wide, flat rib cage, a stiff lower spine, flexible wrists, and shoulder blades that lie along its back. | |
12 Ma | Danuvius guggenmosi is the first-discovered Late Miocene great ape with preserved long bones, and greatly elucidates the anatomical structure and locomotion of contemporary apes.[30] It had adaptations for both hanging in trees (suspensory behavior) and walking on two legs (bipedalism)—whereas, among present-day hominids, humans are better adapted for the latter and the others for the former. Danuvius thus had a method of locomotion unlike any previously known ape called "extended limb clambering", walking directly along tree branches as well as using arms for suspending itself. The last common ancestor between humans and other apes possibly had a similar method of locomotion. | |
12-8 Ma | The clade currently represented by humans and the genus Pan (chimpanzees and bonobos) splits from the ancestors of the gorillas between c. 12 to 8 Ma.[31] | |
8-6 Ma |
The latest common ancestor of humans and chimpanzeesis estimated to have lived between roughly 10 to 5 million years ago. Both chimpanzees and humans have a larynx that repositions during the first two years of life to a spot between the pharynx and the lungs, indicating that the common ancestors have this feature, a precondition for vocalized speech in humans.Speciation may have begun shortly after 10 Ma, but late admixture between the lineages may have taken place until after 5 Ma. Candidates of Hominina or Homininae species which lived in this time period includeOuranopithecus (c. 8 Ma),Graecopithecus (c. 7 Ma),Sahelanthropus tchadensis (c. 7 Ma),Orrorin tugenensis (c. 6 Ma).Ardipithecus is, or may be, a very early hominin genus (tribe Hominini and subtribe Hominina). Two species are described in the literature: A. ramidus, which lived about 4.4 million years ago[32] during the early Pliocene, and A. kadabba, dated to approximately 5.6 million years ago[33] (late Miocene). A. ramidus had a small brain, measuring between 300 and 350 cm3. This is about the same size as the modern bonobo and female chimpanzee brain; it is somewhat smaller than the brain of australopithecines like Lucy (400 to 550 cm3) and slightly over a fifth the size of the modern Homo sapiens brain. Ardipithecus was arboreal, meaning it lived largely in the forest where it competed with other forest animals for food, no doubt including the contemporary ancestor of the chimpanzees. Ardipithecus was probably bipedal as evidenced by its bowl shaped pelvis, the angle of its foramen magnum and its thinner wrist bones, though its feet were still adapted for grasping rather than walking for long distances. | |
4-3.5 Ma | A member of the Australopithecus afarensis left human-like footprints on volcanic ash in Laetoli, northern Tanzania, providing strong evidence of full-time bipedalism. Australopithecus afarensis lived between 3.9 and 2.9 million years ago, and is considered one of the earliest hominins—those species that developed and comprised the lineage of Homo and Homos closest relatives after the split from the line of the chimpanzees. It is thought that A. afarensis was ancestral to both the genus Australopithecus and the genus Homo. Compared to the modern and extinct great apes, A. afarensis had reduced canines and molars, although they were still relatively larger than in modern humans. A. afarensis also has a relatively small brain size (380–430 cm3) and a prognathic (anterior-projecting) face. Australopithecines have been found in savannah environments; they probably developed their diet to include scavenged meat. Analyses of Australopithecus africanus lower vertebrae suggests that these bones changed in females to support bipedalism even during pregnancy. | |
3.5–3.0 Ma | Kenyanthropus platyops, a possible ancestor of Homo, emerges from the Australopithecus. Stone tools are deliberately constructed.[34] | |
3 Ma | The bipedal australopithecines (a genus of the subtribe Hominina) evolve in the savannas of Africa being hunted by Megantereon. Loss of body hair occurs from 3 to 2 Ma, in parallel with the development of full bipedalism and slight enlargement of the brain.[35] |
Date | Event |
---|---|
2.5–2.0 Ma | Early Homo appears in East Africa, speciating from australopithecine ancestors.The Lower Paleolithic is defined by the beginning of use of stone tools.Australopithecus garhi was using stone tools at about 2.5 Ma.Homo habilis is the oldest species given the designation Homo, by Leakey et al. in 1964.H. habilis is intermediate between Australopithecus afarensis and H. erectus, and there have been suggestions to re-classify it within genus Australopithecus, as Australopithecus habilis. Stone tools found at the Shangchen site in China and dated to 2.12 million years ago are considered the earliest known evidence of hominins outside Africa, surpassing Dmanisi in Georgia by 300,000 years.[36] |
1.9–0.8 Ma | Homo erectus derives from early Homo or late Australopithecus. Homo habilis, although significantly different of anatomy and physiology, is thought to be the ancestor of Homo ergaster, or African Homo erectus; but it is also known to have coexisted with H. erectus for almost half a million years (until about 1.5 Ma).From its earliest appearance at about 1.9 Ma, H. erectus is distributed in East Africa and Southwest Asia (Homo georgicus). H. erectus is the first known species to develop control of fire, by about 1.5 Ma. H. erectus later migrates throughout Eurasia, reaching Southeast Asia by 0.7 Ma.It is described in a number of subspecies.[37] Early humans were social and initially scavenged, before becoming active hunters. The need to communicate and hunt prey efficiently in a new, fluctuating environment (where the locations of resources need to be memorized and told) may have driven the expansion of the brain from 2 to 0.8 Ma. Evolution of dark skin at about 1.2 Ma.[38] Homo antecessor may be a common ancestor of humans and Neanderthals.[39] [40] At present estimate, humans have approximately 20,000–25,000 genes and share 99% of their DNA with the now extinct Neanderthal[41] and 95–99% of their DNA with their closest living evolutionary relative, the chimpanzees.[42] [43] The human variant of the FOXP2 gene (linked to the control of speech) has been found to be identical in Neanderthals.[44] |
0.8–0.3 Ma | Divergence of Neanderthal and Denisovan lineages from a common ancestor.[45] Homo heidelbergensis (in Africa also known as Homo rhodesiensis) had long been thought to be a likely candidate for the last common ancestor of the Neanderthal and modern human lineages.However, genetic evidence from the Sima de los Huesos fossils published in 2016 seems to suggest that H. heidelbergensis in its entirety should be included in the Neanderthal lineage, as "pre-Neanderthal" or "early Neanderthal", while the divergence time between the Neanderthal and modern lineages has been pushed back to before the emergence of H. heidelbergensis, to about 600,000 to 800,000 years ago, the approximate age of Homo antecessor.[46] [47] Brain expansion (enlargement) between 0.8 and 0.2 Ma may have occurred due to the extinction of most African megafauna (which made humans feed from smaller prey and plants, which required greater intelligence due to greater speed of the former and uncertainty about whether the latter were poisonous or not), extreme climate variability after Mid-Pleistocene Transition (which intensified the situation, and resulted in frequent migrations), and in general selection for more social life (and intelligence) for greater chance of survival, reproductivity, and care for mothers. Solidified footprints dated to about 350 ka and associated with H. heidelbergensis were found in southern Italy in 2003.[48] H. sapiens lost the brow ridges from their hominid ancestors as well as the snout completely, though their noses evolve to be protruding (possibly from the time of H. erectus). By 200 ka, humans had stopped their brain expansion. |
See also: Neanderthal, Interbreeding between archaic and modern humans, Recent human evolution and Human genetic variation.
Date | Event |
---|---|
300–130 ka | Neanderthals and Denisovans emerge from the northern Homo heidelbergensis lineage around 500-450 ka while sapients emerge from the southern lineage around 350-300 ka.[49] Fossils attributed to H. sapiens, along with stone tools, dated to approximately 300,000 years ago, found at Jebel Irhoud, Morocco[50] yield the earliest fossil evidence for anatomically modern Homo sapiens.Modern human presence in East Africa (Gademotta), at 276 kya.[51] In July 2019, anthropologists reported the discovery of 210,000 year old remains of a H. sapiens in Apidima Cave, Peloponnese, Greece.[52] [53] [54] Patrilineal and matrilineal most recent common ancestors (MRCAs) of living humans roughly between 200 and 100 kya[55] [56] with some estimates on the patrilineal MRCA somewhat higher, ranging up to 250 to 500 kya.[57] 160,000 years ago, Homo sapiens idaltu in the Awash River Valley (near present-day Herto village, Ethiopia) practiced excarnation.[58] |
130–80 ka | Marine Isotope Stage 5 (Eemian).Modern human presence in Southern Africa and West Africa.[59] Appearance of mitochondrial haplogroup (mt-haplogroup) L2. |
80–50 ka | MIS 4, beginning of the Upper Paleolithic.Early evidence for behavioral modernity.[60] Appearance of mt-haplogroups M and N. Southern Dispersal migration out of Africa, Proto-Australoid peopling of Oceania.[61] Archaic admixture from Neanderthals in Eurasia,[62] [63] from Denisovans in Oceania with trace amounts in Eastern Eurasia,[64] and from an unspecified African lineage of archaic humans in Sub-Saharan Africa as well as an interbred species of Neanderthals and Denisovans in Asia and Oceania.[65] [66] [67] [68] |
50–25 ka | Behavioral modernity develops by this time or earlier, according to the "great leap forward" theory.[69] Extinction of Homo floresiensis.[70] M168 mutation (carried by all non-African males).Appearance of mt-haplogroups U and K.Peopling of Europe, peopling of the North Asian Mammoth steppe. Paleolithic art.Extinction of Neanderthals and other archaic human variants (with possible survival of hybrid populations in Asia and Africa.)Appearance of Y-Haplogroup R2; mt-haplogroups J and X. |
after 25 ka | Last Glacial Maximum
Extinction of late surviving archaic humans at the beginning of the Holocene (12 ka).Accelerated divergence due to selection pressures in populations participating in the Neolithic Revolution after 12 ka, e.g.East Asian types of ADH1B associated with rice domestication,[73] or lactase persistence.[74] [75] A slight decrease in brain size occurred a few thousand years ago. |