Australopithecus afarensis

(Redirected from Au. afarensis)

Australopithecus afarensis is an extinct species of australopithecine which lived from about 3.9–2.9 million years ago (mya) in the Pliocene of East Africa. The first fossils were discovered in the 1930s, but major fossil finds would not take place until the 1970s. From 1972 to 1977, the International Afar Research Expedition—led by anthropologists Maurice Taieb, Donald Johanson and Yves Coppens—unearthed several hundreds of hominin specimens in Hadar, Ethiopia, the most significant being the exceedingly well-preserved skeleton AL 288-1 ("Lucy") and the site AL 333 ("the First Family"). Beginning in 1974, Mary Leakey led an expedition into Laetoli, Tanzania, and notably recovered fossil trackways. In 1978, the species was first described, but this was followed by arguments for splitting the wealth of specimens into different species given the wide range of variation which had been attributed to sexual dimorphism (normal differences between males and females). A. afarensis probably descended from A. anamensis and is hypothesised to have given rise to Homo, though the latter is debated.

Australopithecus afarensis
Temporal range: ZancleanPiacenzian
3.9–2.9 Ma
The partial skeleton AL 288-1 ("Lucy")
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Primates
Suborder: Haplorhini
Infraorder: Simiiformes
Family: Hominidae
Subfamily: Homininae
Tribe: Hominini
Genus: Australopithecus
Species:
A. afarensis
Binomial name
Australopithecus afarensis
Synonyms
Synonyms

A. afarensis had a tall face, a delicate brow ridge, and prognathism (the jaw jutted outwards). The jawbone was quite robust, similar to that of gorillas. The living size of A. afarensis is debated, with arguments for and against marked size differences between males and females. Lucy measured perhaps 105 cm (3 ft 5 in) in height and 25–37 kg (55–82 lb), but she was rather small for her species. In contrast, a presumed male was estimated at 165 cm (5 ft 5 in) and 45 kg (99 lb). A perceived difference in male and female size may simply be sampling bias. The leg bones as well as the Laetoli fossil trackways suggest A. afarensis was a competent biped, though somewhat less efficient at walking than humans. The arm and shoulder bones have some similar aspects to those of orangutans and gorillas, which has variously been interpreted as either evidence of partial tree-dwelling (arboreality), or basal traits inherited from the chimpanzee–human last common ancestor with no adaptive functionality.

A. afarensis was probably a generalist omnivore of both C3 forest plants and C4 CAM savanna plants—and perhaps creatures which ate such plants—and was able to exploit a variety of different food sources. Similarly, A. afarensis appears to have inhabited a wide range of habitats with no real preference, inhabiting open grasslands or woodlands, shrublands, and lake- or riverside forests. Potential evidence of stone tool use would indicate meat was also a dietary component. Marked sexual dimorphism in primates typically corresponds to a polygynous society and low dimorphism to monogamy, but the group dynamics of early hominins is difficult to predict with accuracy. Early hominins may have fallen prey to the large carnivores of the time, such as big cats and hyenas.

Taxonomy

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Research history

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Beginning in the 1930s, some of the most ancient hominin remains of the time dating to 3.8–2.9 million years ago were recovered from East Africa. Because Australopithecus africanus fossils were commonly being discovered throughout the 1920s and '40s in South Africa, these remains were often provisionally classified as Australopithecus aff. africanus.[1] The first to identify a human fossil was German explorer Ludwig Kohl-Larsen in 1939 by the headwaters of the Gerusi River (near Laetoli, Tanzania), who encountered a maxilla.[2] In 1948, German palaeontologist Edwin Hennig proposed classifying it into a new genus, "Praeanthropus", but he failed to give a species name. In 1950, German anthropologist Hans Weinert proposed classifying it as Meganthropus africanus, but this was largely ignored. In 1955, M.S. Şenyürek proposed the combination Praeanthropus africanus.[1] Major collections were made in Laetoli, Tanzania, on an expedition beginning in 1974 directed by British palaeoanthropologist Mary Leakey, and in Hadar, Ethiopia, from 1972 to 1977 by the International Afar Research Expedition (IARE) formed by French geologist Maurice Taieb, American palaeoanthropologist Donald Johanson and Breton anthropologist Yves Coppens. These fossils were remarkably well preserved and many had associated skeletal aspects.[3]: 5  In 1973, the IARE team unearthed the first knee joint, AL 129-1, and showed the earliest example at the time of bipedalism. On 24 November 1974, Johanson and graduate student Tom Gray discovered the extremely well-preserved skeleton AL 288–1, commonly referred to as "Lucy" (named after the 1967 Beatles song Lucy in the Sky with Diamonds which was playing on their tape recorder that evening).[4] In 1975, the IARE recovered 216 specimens belonging to 13 individuals, AL 333 "the First Family" (though the individuals were not necessarily related).[5]: 471–472  In 1976, Leakey and colleagues discovered fossil trackways, and preliminarily classified Laetoli remains into Homo spp., attributing Australopithecus-like traits as evidence of them being transitional fossils.[6]

 
The holotype LH 4

In 1978, Johanson, Tim D. White and Coppens classified the hundreds of specimens collected thus far from both Hadar and Laetoli into a single new species, A. afarensis, and considered the apparently wide range of variation a result of sexual dimorphism. The species name honours the Afar Region of Ethiopia where the majority of the specimens had been recovered from. They later selected the jawbone LH 4 as the holotype specimen because of its preservation quality and because White had already fully described and illustrated it the year before.[1]

 
Locations of A. afarensis sites

A. afarensis is known only from East Africa. Beyond Laetoli and the Afar Region, the species has been recorded in Kenya at Koobi Fora and possibly Lothagam; and elsewhere in Ethiopia at Woranso-Mille, Maka, Belohdelie, Ledi-Geraru and Fejej.[7][8] The frontal bone fragment BEL-VP-1/1 from the Middle Awash,[9] Afar Region, Ethiopia, dating to 3.9 million years ago has typically been assigned to A. anamensis based on age, but may be assignable to A. afarensis because it exhibits a derived form of postorbital constriction. This would mean A. afarensis and A. anamensis coexisted for at least 100,000 years.[10] In 2005, a second adult specimen preserving both skull and body elements, AL 438–1, was discovered in Hadar.[11] In 2006, an infant partial skeleton, DIK-1-1, was unearthed at Dikika, Afar Region.[12] In 2015, an adult partial skeleton, KSD-VP-1/1, was recovered from Woranso-Mille.[13]: 1–4 

For a long time, A. afarensis was the oldest known African great ape until the 1994 description of the 4.4-million-year-old Ardipithecus ramidus,[14] and a few earlier or contemporary taxa have been described since, including the 4-million-year-old A. anamensis in 1995,[15] the 3.5-million-year-old Kenyanthropus platyops in 2001,[16] the 6-million-year-old Orrorin tugenensis in 2001,[17] and the 7- to 6-million-year-old Sahelanthropus tchadensis in 2002.[18] Bipedalism was once thought to have evolved in australopithecines, but it is now thought to have begun evolving much earlier in habitually arboreal primates. The earliest claimed date for the beginnings of an upright spine and a primarily vertical body plan is 21.6 million years ago in the Early Miocene with Morotopithecus bishopi.[19]

Classification

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A. afarensis is now a widely accepted species, and it is now generally thought that Homo and Paranthropus are sister taxa deriving from Australopithecus, but the classification of Australopithecus species is in disarray. Australopithecus is considered a grade taxon whose members are united by their similar physiology rather than close relations with each other over other hominin genera. It is unclear how any Australopithecus species relate to each other,[20] but it is generally thought that a population of A. anamensis evolved into A. afarensis.[10][20][21]

In 1979, Johanson and White proposed that A. afarensis was the last common ancestor between Homo and Paranthropus, supplanting A. africanus in this role.[22] Considerable debate of the validity of this species followed, with proposals for synonymising them with A. africanus or recognising multiple species from the Laetoli and Hadar remains. In 1980, South African palaeoanthropologist Phillip V. Tobias proposed reclassifying the Laetoli specimens as A. africanus afarensis and the Hadar specimens as A. afr. aethiopicus.[23] The skull KNM-ER 1470 (now H. rudolfensis) was at first dated to 2.9 million years ago, which cast doubt on the ancestral position of both A. afarensis or A. africanus, but it has been re-dated to about 2 million years ago.[8] Several Australopithecus species have since been postulated to represent the ancestor to Homo, but the 2013 discovery of the earliest Homo specimen, LD 350-1, 2.8 million years old (older than almost all other Australopithecus species) from the Afar Region could potentially affirm A. afarensis' ancestral position.[24] However, A. afarensis is also argued to have been too derived (too specialised), due to resemblance in jaw anatomy to the robust australopithecines, to have been a human ancestor.[25]

Palaeoartist Walter Ferguson has proposed splitting A. afarensis into "H. antiquus", a relict dryopithecine "Ramapithecus" (now Kenyapithecus) and a subspecies of A. africanus. His recommendations have largely been ignored.[26][8] In 2003, Spanish writer Camilo José Cela Conde and evolutionary biologist Francisco J. Ayala proposed reinstating "Praeanthropus" including A. afarensis alongside Sahelanthropus, A. anamensis, A. bahrelghazali and A. garhi.[27] In 2004, Danish biologist Bjarne Westergaard and geologist Niels Bonde proposed splitting off "Homo hadar" with the 3.2-million-year-old partial skull AL 333–45 as the holotype, because a foot from the First Family was apparently more humanlike than that of Lucy. In 2011, Bonde agreed with Ferguson that Lucy should be split into a new species, though erected a new genus as "Afaranthropus antiquus".[28]

In 1996, a 3.6-million-year-old jaw from Koro Toro, Chad, originally classified as A. afarensis was split off into a new species as A. bahrelghazali.[29] In 2015, some 3.5- to 3.3-million-year-old jaw specimens from the Afar Region (the same time and place as A. afarensis) were classified as a new species as A. deyiremeda, and the recognition of this species would call into question the species designation of fossils currently assigned to A. afarensis.[30] However, the validity of A. bahrelghazali and A. deyiremeda is debated.[31] Wood and Boyle (2016) stated there was "low confidence" that A. afarensis, A. bahrelghazali and A. deyiremeda are distinct species, with Kenyanthropus platyops perhaps being indistinct from the latter two.[32]

African hominin timeline (in mya)
View references
H. sapiensH. nalediH. rhodesiensisH. ergasterAu. sedibaP. robustusP. boiseiH. rudolfensisH. habilisAu. garhiP. aethiopicusLD 350-1K. platyopsAu. bahrelghazaliAu. deyiremedaAu. africanusAu. afarensisAu. anamensisAr. ramidusAr. kadabba


Anatomy

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Skull

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Two A. afarensis skulls

A. afarensis had a tall face, a delicate brow ridge, and prognathism (the jaw jutted outwards). One of the biggest skulls, AL 444–2, is about the size of a female gorilla skull.[33] The first relatively complete jawbone was discovered in 2002, AL 822–1. This specimen strongly resembles the deep and robust gorilla jawbone. However, unlike gorillas, the strength of the sagittal and nuchal crests (which support the temporalis muscle used in biting) do not vary between sexes. The crests are similar to those of chimpanzees and female gorillas.[25] Compared to earlier hominins, the incisors of A. afarensis are reduced in breadth, the canines reduced in size and lost the honing mechanism which continually sharpens them, the premolars are molar-shaped, and the molars are taller.[34] The molars of australopiths are generally large and flat with thick enamel, which is ideal for crushing hard and brittle foods.[35]

The brain volume of Lucy was estimated to have been 365–417 cc, specimen AL 822-1 about 374–392 cc, AL 333-45 about 486–492 cc, and AL 444-2 about 519–526 cc. This would make for an average of about 445 cc. The brain volumes of the infant (about 2.5 years of age) specimens DIK-1-1 and AL 333-105 are 273–277 and 310–315 cc, respectively. Using these measurements, the brain growth rate of A. afarensis was closer to the growth rate of modern humans than to the faster rate in chimpanzees. Though brain growth was prolonged, the duration was nonetheless much shorter than modern humans, which is why the adult A. afarensis brain was so much smaller. The A. afarensis brain was likely organised like non-human ape brains, with no evidence for humanlike brain configuration.[36]

Size

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Reconstruction of a male (left) and female (right) A. afarensis at the Natural History Museum, Vienna

A. afarensis specimens apparently exhibit a wide range of variation, which is generally explained as marked sexual dimorphism with males much bigger than females. In 1991, American anthropologist Henry McHenry estimated body size by measuring the joint sizes of the leg bones and scaling down a human to meet that size. This yielded 151 cm (4 ft 11 in) for a presumed male (AL 333–3), whereas Lucy was 105 cm (3 ft 5 in).[37] In 1992, he estimated that males typically weighed about 44.6 kg (98 lb) and females 29.3 kg (65 lb) assuming body proportions were more humanlike than apelike. This gives a male to female body mass ratio of 1.52, compared to 1.22 in modern humans, 1.37 in chimpanzees, and about 2 for gorillas and orangutans.[38] However, this commonly cited weight figure used only three presumed-female specimens, of which two were among the smallest specimens recorded for the species. It is also contested if australopiths even exhibited heightened sexual dimorphism at all, which if correct would mean the range of variation is normal body size disparity between different individuals regardless of sex. It has also been argued that the femoral head could be used for more accurate size modeling, and the femoral head size variation was the same for both sexes.[39]

Lucy is one of the most complete Pliocene hominin skeletons, with over 40% preserved, but she was one of the smaller specimens of her species. Nonetheless, she has been the subject of several body mass estimates since her discovery, ranging from 13–42 kg (29–93 lb) for absolute lower and upper bounds. Most studies report ranges within 25–37 kg (55–82 lb).[40]

For the five makers of the Laetoli fossil trackways (S1, S2, G1, G2 and G3), based on the relationship between footprint length and bodily dimensions in modern humans, S1 was estimated to have been considerably large at about 165 cm (5 ft 5 in) tall and 45 kg (99 lb) in weight, S2 145 cm (4 ft 9 in) and 39.5 kg (87 lb), G1 114 cm (3 ft 9 in) and 30 kg (66 lb), G2 142 cm (4 ft 8 in) and 39 kg (86 lb), and G3 132 cm (4 ft 4 in) and 35 kg (77 lb). Based on these, S1 is interpreted to have been a male, and the rest females (G1 and G3 possibly juveniles), with A. afarensis being a highly dimorphic species.[41]

Torso

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DIK-1-1 preserves an oval hyoid bone (which supports the tongue) more similar to those of chimpanzees and gorillas than the bar-shaped hyoid of humans and orangutans. This would suggest the presence of laryngeal air sacs characteristic of non-human African apes (and large gibbons).[12] Air sacs may lower the risk of hyperventilating when producing faster extended call sequences by rebreathing exhaled air from the air sacs. The loss of these in humans could have been a result of speech and resulting low risk of hyperventilating from normal vocalisation patterns.[42]

It was previously thought that the australopithecines' spine was more like that of non-human apes than humans, with weak neck vertebrae. However, the thickness of the neck vertebrae of KSD-VP-1/1 is similar to that of modern humans. Like humans, the series has a bulge and achieves maximum girth at C5 and 6, which in humans is associated with the brachial plexus, responsible for nerves and muscle innervation in the arms and hands. This could perhaps speak to advanced motor functions in the hands of A. afarensis and competency at precision tasks compared to non-human apes, possibly implicated in stone tool use or production.[43][13]: 63–111  However, this could have been involved in head stability or posture rather than dexterity. A.L. 333-101 and A.L. 333-106 lack evidence of this feature. The neck vertebrae of KDS-VP-1/1 indicate that the nuchal ligament, which stabilises the head while distance running in humans and other cursorial creatures, was either not well developed or absent.[13]: 92–95  KSD-VP-1/1, preserving (among other skeletal elements) 6 rib fragments, indicates that A. afarensis had a bell-shaped ribcage instead of the barrel shaped ribcage exhibited in modern humans. Nonetheless, the constriction at the upper ribcage was not so marked as exhibited in non-human great apes and was quite similar to humans.[13]: 143–153  Originally, the vertebral centra preserved in Lucy were interpreted as being the T6, T8, T10, T11 and L3, but a 2015 study instead interpreted them as being T6, T7, T9, T10 and L3.[44] DIK-1-1 shows that australopithecines had 12 thoracic vertebrae like modern humans instead of 13 like non-human apes.[45] Like humans, australopiths likely had 5 lumbar vertebrae, and this series was likely long and flexible in contrast to the short and inflexible non-human great ape lumbar series.[13]: 143–153 

Upper limbs

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"Lucy" skeleton

Like other australopiths, the A. afarensis skeleton exhibits a mosaic anatomy with some aspects similar to modern humans and others to non-human great apes. The pelvis and leg bones clearly indicate weight-bearing ability, equating to habitual bipedalism, but the upper limbs are reminiscent of orangutans, which would indicate arboreal locomotion. However, this is much debated, as tree-climbing adaptations could simply be basal traits inherited from the great ape last common ancestor in the absence of major selective pressures at this stage to adopt a more humanlike arm anatomy.[46]

The shoulder joint is somewhat in a shrugging position, closer to the head, like in non-human apes.[47] Juvenile modern humans have a somewhat similar configuration, but this changes to the normal human condition with age; such a change does not appear to have occurred in A. afarensis development. It was once argued that this was simply a byproduct of being a small-bodied species, but the discovery of the similarly sized H. floresiensis with a more or less human shoulder configuration and larger A. afarensis specimens retaining the shrugging shoulders show this to not have been the case. The scapular spine (reflecting the strength of the back muscles) is closer to the range of gorillas.[47]

The forearm of A. afarensis is incompletely known, yielding various brachial indexes (radial length divided by humeral length) comparable to non-human great apes at the upper estimate and to modern humans at the lower estimate. The most complete ulna specimen, AL 438–1, is within the range of modern humans and other African apes. However, the L40-19 ulna is much longer, though well below that exhibited in orangutans and gibbons. The AL 438-1 metacarpals are proportionally similar to those of modern humans and orangutans.[48] The A. afarensis hand is quite humanlike, though there are some aspects similar to orangutan hands which would have allowed stronger flexion of the fingers, and it probably could not handle large spherical or cylindrical objects very efficiently. Nonetheless, the hand seems to have been able to have produced a precision grip necessary in using stone tools.[49] However, it is unclear if the hand was capable of producing stone tools.[50]

Lower limbs

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The australopith pelvis is platypelloid and maintains a relatively wider distance between the hip sockets and a more oval shape. Despite being much smaller, Lucy's pelvic inlet is 132 mm (5.2 in) wide, about the same breadth as that of a modern human woman. These were likely adaptations to minimise how far the centre of mass drops while walking upright in order to compensate for the short legs (rotating the hips may have been more important for A. afarensis). Likewise, later Homo could reduce relative pelvic inlet size probably due to the elongation of the legs. Pelvic inlet size may not have been due to fetal head size (which would have increased birth canal and thus pelvic inlet width) as an A. afarensis newborn would have had a similar or smaller head size compared to that of a newborn chimpanzee.[51][52] It is debated if the platypelloid pelvis provided poorer leverage for the hamstrings or not.[51]

 
DIK-1-1 skeleton; notice the diverging left big toe bone

The heel bone of A. afarensis adults and modern humans have the same adaptations for bipedality, indicating a developed grade of walking. The big toe is not dextrous as is in non-human apes (it is adducted), which would make walking more energy efficient at the expense of arboreal locomotion, no longer able to grasp onto tree branches with the feet.[53] However, the foot of the infantile specimen DIK-1-1 indicates some mobility of the big toe, though not to the degree in non-human primates. This would have reduced walking efficiency, but a partially dextrous foot in the juvenile stage may have been important in climbing activities for food or safety, or made it easier for the infant to cling onto and be carried by an adult.[54]

Palaeobiology

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Diet and technology

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A. afarensis was likely a generalist omnivore. Carbon isotope analysis on teeth from Hadar and Dikika 3.4–2.9 million years ago suggests a widely ranging diet between different specimens, with forest-dwelling specimens showing a preference for C3 forest plants, and bush- or grassland-dwelling specimens a preference for C4 CAM savanna plants. C4 CAM sources include grass, seeds, roots, underground storage organs, succulents and perhaps creatures which ate those, such as termites. Thus, A. afarensis appears to have been capable of exploiting a variety of food resources in a wide range of habitats. In contrast, the earlier A. anamensis and Ar. ramidus, as well as modern savanna chimpanzees, target the same types of food as forest-dwelling counterparts despite living in an environment where these plants are much less abundant. Few modern primate species consume C4 CAM plants.[55] The dental anatomy of A. afarensis is ideal for consuming hard, brittle foods, but microwearing patterns on the molars suggest that such foods were infrequently consumed, probably as fallback items in leaner times.[56]

In 2009 at Dikika, Ethiopia, a rib fragment belonging to a cow-sized hoofed animal and a partial femur of a goat-sized juvenile bovid was found to exhibit cut marks, and the former some crushing, which were initially interpreted as the oldest evidence of butchering with stone tools. If correct, this would make it the oldest evidence of sharp-edged stone tool use at 3.4 million years old, and would be attributable to A. afarensis as it is the only species known within the time and place.[57] However, because the fossils were found in a sandstone unit (and were modified by abrasive sand and gravel particles during the fossilisation process), the attribution to hominin activity is weak.[58]

Society

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It is highly difficult to speculate with accuracy the group dynamics of early hominins.[59] A. afarensis is typically reconstructed with high levels of sexual dimorphism, with males much larger than females. Using general trends in modern primates, high sexual dimorphism usually equates to a polygynous society due to intense male–male competition over females, like in the harem society of gorillas. However, it has also been argued that A. afarensis had much lower levels of dimorphism, and so had a multi-male kin-based society like chimpanzees. Low dimorphism could also be interpreted as having had a monogamous society with strong male–male competition. Contrarily, the canine teeth are much smaller in A. afarensis than in non-human primates, which should indicate lower aggression because canine size is generally positively correlated with male–male aggression.[60][61][62]

Birth

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Diagram comparing birthing mechanisms of a chimpanzee (left), A. afarensis (middle) and a modern human (right)

The platypelloid pelvis may have caused a different birthing mechanism from modern humans, with the neonate entering the inlet facing laterally (the head was transversally orientated) until it exited through the pelvic outlet. This would be a non-rotational birth, as opposed to a fully rotational birth in humans. However, it has been suggested that the shoulders of the neonate may have been obstructed, and the neonate could have instead entered the inlet transversely and then rotated so that it exited through the outlet oblique to the main axis of the pelvis, which would be a semi-rotational birth. By this argument, there may not have been much space for the neonate to pass through the birth canal, causing a difficult childbirth for the mother.[63]

Gait

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Overview of the S1 trackway (above) and image of the L8 test-pit (below)

The Laetoli fossil trackway, generally attributed to A. afarensis, indicates a rather developed grade of bipedal locomotion, more efficient than the bent-hip–bent-knee (BHBK) gait used by non-human great apes (though earlier interpretations of the gait include a BHBK posture or a shuffling movement). Trail A consists of short, broad prints resembling those of a two-and-a-half-year-old child, though it has been suggested this trail was made by the extinct bear Agriotherium africanus. G1 is a trail consisting of four cycles likely made by a child. G2 and G3 are thought to have been made by two adults.[64] In 2014, two more trackways were discovered made by one individual, named S1, extending for a total of 32 m (105 ft). In 2015, a single footprint from a different individual, S2, was discovered.[41]

The shallowness of the toe prints would indicate a more flexed limb posture when the foot hit the ground and perhaps a less arched foot, meaning A. afarensis was less efficient at bipedal locomotion than humans.[65] Some tracks feature a 100 mm (3.9 in) long drag mark probably left by the heel, which may indicate the foot was lifted at a low angle to the ground. For push-off, it appears weight shifted from the heel to the side of the foot and then the toes. Some footprints of S1 either indicate asymmetrical walking where weight was sometimes placed on the anterolateral part (the side of the front half of the foot) before toe-off, or sometimes the upper body was rotated mid-step. The angle of gait (the angle between the direction the foot is pointing in on touchdown and median line drawn through the entire trackway) ranges from 2–11° for both right and left sides. G1 generally shows wide and asymmetrical angles, whereas the others typically show low angles.[41]

The speed of the track makers has been variously estimated depending on the method used, with G1 reported at 0.47, 0.56, 0.64, 0.7 and 1 m/s (1.69, 2, 2.3, 2.5 and 3.6 km/h; 1.1, 1.3, 1.4, 1.6 and 2.2 mph); G2/3 reported at 0.37, 0.84 and 1 m/s (1.3, 2.9 and 3.6 km/h; 0.8, 1.8 and 2.2 mph);[64][41] and S1 at 0.51 or 0.93 m/s (1.8 or 3.3 km/h; 1.1 or 2.1 mph).[41] For comparison, modern humans typically walk at 1–1.7 m/s (3.6–6.1 km/h; 2.2–3.8 mph).[64]

The average step distance is 568 mm (1.86 ft), and stride distance 1,139 mm (3.74 ft). S1 appears to have had the highest average step and stride length of, respectively, 505–660 mm2 (0.783–1.023 sq in) and 1,044–1,284 mm (3.43–4.21 ft) whereas G1–G3 averaged, respectively, 416, 453 and 433 mm (1.4, 1.5 and 1.4 ft) for step and 829, 880 and 876 mm (2.7, 2.9 and 2.9 ft) for stride.[41]

Pathology

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Australopithecines, in general, seem to have had a high incidence rate of vertebral pathologies, possibly because their vertebrae were better adapted to withstand suspension loads in climbing than compressive loads while walking upright.[13]: 95–97  Lucy presents marked thoracic kyphosis (hunchback) and was diagnosed with Scheuermann's disease, probably caused by overstraining her back, which can lead to a hunched posture in modern humans due to irregular curving of the spine. Because her condition presented quite similarly to that seen in modern human patients, this would indicate a basically human range of locomotor function in walking for A. afarensis. The original straining may have occurred while climbing or swinging in the trees, though, even if correct, this does not indicate that her species was maladapted for arboreal behaviour, much like how humans are not maladapted for bipedal posture despite developing arthritis.[66] KSD-VP-1/1 seemingly exhibits compensatory action by the neck and lumbar vertebrae (gooseneck) consistent with thoracic kyphosis and Scheuermann's disease, but thoracic vertebrae are not preserved in this specimen.[13]: 95–97 

In 2010, KSD-VP-1/1 presented evidence of a valgus deformity of the left ankle involving the fibula, with a bony ring developing on the fibula's joint surface extending the bone an additional 5–10 mm (0.20–0.39 in). This was probably caused by a fibular fracture during childhood which improperly healed in a nonunion.[13]: 162–163 

In 2016, palaeoanthropologist John Kappelman argued that the fracturing exhibited by Lucy was consistent with a proximal humerus fracture, which is most often caused by falling in humans. He then concluded she died from falling out of a tree, and that A. afarensis slept in trees or climbed trees to escape predators. However, similar fracturing is exhibited in many other creatures in the area, including the bones of antelope, elephants, giraffes and rhinos, and may well simply be taphonomic bias (fracturing was caused by fossilisation).[67] Lucy may also have been killed in an animal attack or a mudslide.[68]

The 13 AL 333 individuals are thought to have been deposited at about the same time as one another, bear little evidence of carnivore activity, and were buried on a 7 m (23 ft) stretch of a hill. In 1981, anthropologists James Louis Aronson and Taieb suggested they were killed in a flash flood. British archaeologist Paul Pettitt considered natural causes unlikely and, in 2013, speculated that these individuals were purposefully hidden in tall grass by other hominins (funerary caching).[69] This behaviour has been documented in modern primates, and may be done so that the recently deceased do not attract predators to living grounds.[70]

Palaeoecology

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A. afarensis does not appear to have had a preferred environment, and inhabited a wide range of habitats such as open grasslands or woodlands, shrublands, and lake- or riverside forests.[7] Likewise, the animal assemblage varied widely from site to site. The Pliocene of East Africa was warm and wet compared to the preceding Miocene, with the dry season lasting about four months based on floral, faunal, and geological evidence. The extended rainy season would have made more desirable foods available to hominins for most of the year.[71] During the Late Pliocene around 4–3 million years ago, Africa featured a greater diversity of large carnivores than today, and australopithecines likely fell prey to these dangerous creatures, including hyenas, Panthera, cheetahs, and the saber-toothed cats: Megantereon, Dinofelis, Homotherium and Machairodus.[72]

Australopithecines and early Homo likely preferred cooler conditions than later Homo, as there are no australopithecine sites that were below 1,000 m (3,300 ft) in elevation at the time of deposition. This would mean that, like chimpanzees, they often inhabited areas with an average diurnal temperature of 25 °C (77 °F), dropping to 10 or 5 °C (50 or 41 °F) at night.[73] At Hadar, the average temperature from 3.4 to 2.95 million years ago was about 20.2 °C (68.4 °F).[74]

See also

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References

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  1. ^ a b c d Johanson, Donald C.; White, Tim D.; Coppens, Yves (1978). "A New Species of the Genus Australopithecus (Primates: Hominidae) from the Pliocene of Eastern Africa". Kirtlandia. 28: 1–14.
  2. ^ Morell, V. (2011). Ancestral Passions: The Leakey Family and the Quest for Humankind's Beginnings. Simon and Schuster. p. 445. ISBN 978-1-4391-4387-2.
  3. ^ Kimbel, W. H.; Delezene, L. K. (2009). ""Lucy" Redux: A Review of Research on Australopithecus afarensis". American Journal of Physical Anthropology. 49: 2–48. doi:10.1002/ajpa.21183. PMID 19890859.
  4. ^ Johanson, D. (1990). "Prologue". Lucy: The Beginnings of Humankind. Simon and Schuster. ISBN 978-0-671-72499-3.
  5. ^ Johanson, D. C. (2004). "Lucy, Thirty Years Later: An Expanded View of Australopithecus afarensis". Journal of Anthropological Research. 60 (4): 465–486. doi:10.1086/jar.60.4.3631138. JSTOR 3631138. S2CID 159745450.
  6. ^ Leakey, M.; Ray, R. H.; Curtis, G. H.; Drake, R. E.; Jackes, M. K.; White, T. D. (1976). "Fossil hominids from the Laetolil Beds". Nature. 262 (5568): 460–466. Bibcode:1976Natur.262..460L. doi:10.1038/262460a0. hdl:2027.42/62755. PMID 822342. S2CID 4151505.
  7. ^ a b Behrensmeyer, A. K.; Reed, K. E. (2013). "Reconstructing the Habitats of Australopithecus: Paleoenvironments, Site Taphonomy, and Faunas". In Reed, K. E.; Fleagle, J. G.; Leakey, R. E. (eds.). The Paleobiology of Australopithecus. Springer Science and Business Media. pp. 53–54. ISBN 978-94-007-5919-0.
  8. ^ a b c Delson, E.; Tattersall, I.; Van Couvering, J.; Brooks, A. S. (2004). Encyclopedia of Human Evolution and Prehistory (2nd ed.). Routledge. pp. 118–120. ISBN 978-1-135-58228-9.
  9. ^ Facts about the Oromo of East Africa, May 26, 1995, archived from the original on January 28, 2021, retrieved April 6, 2021
  10. ^ a b Haile-Selassie, Y.; M. Melillo, S.; Vazzana, A.; Benazzi, S.; T., M. Ryan (2019). "A 3.8-million-year-old hominin cranium from Woranso-Mille, Ethiopia". Nature. 573 (7773): 214–219. Bibcode:2019Natur.573..214H. doi:10.1038/s41586-019-1513-8. hdl:11585/697577. PMID 31462770. S2CID 201656331.
  11. ^ Drapeau, M. S. M.; Ward, C. V.; Kimbel, W. H.; Johanson, D. C.; Rak, Y. (2005). "Associated Cranial and Forelimb Remains Attributed to Australopithecus afarensis From Hadar, Ethiopia". Journal of Human Evolution. 48 (6): 593–642. Bibcode:2005JHumE..48..593D. doi:10.1016/j.jhevol.2005.02.005. PMID 15927662.
  12. ^ a b Alamseged, Z.; Spoor, F.; Kimbel, W. H.; Bobe, R.; Geraads, D.; Reed, D.; Wynn, J. G. (2006). "A juvenile early hominin skeleton from Dikika, Ethiopia". Nature. 443 (7109): 296–301. Bibcode:2006Natur.443..296A. doi:10.1038/nature05047. PMID 16988704. S2CID 4418369.
  13. ^ a b c d e f g h Haile-Selassie, Y.; Su, D. F. (2015). The Postcranial Anatomy of Australopithecus afarensis: New Insights from KSD-VP-1/1. Vertebrate Paleobiology and Paleoanthropology. Springer. doi:10.1007/978-94-017-7429-1. ISBN 978-94-017-7429-1. S2CID 133164058.
  14. ^ Suwa, G; Asfaw, B.; Kono, R. T.; Kubo, D.; Lovejoy, C. O.; White, T. D.; et al. (2 October 2009). "The Ardipithecus ramidus skull and its implications for hominid origins" (PDF). Science. 326 (5949): 68, 68e1–68e7. Bibcode:2009Sci...326...68S. doi:10.1126/science.1175825. PMID 19810194. S2CID 19725410.
  15. ^ Leakey, M. G.; Feibel, C. S.; MacDougall, I.; Walker, A. (1995). "New four-million-year-old hominid species from Kanapoi and Allia Bay, Kenya". Nature. 376 (6541): 565–571. Bibcode:1995Natur.376..565L. doi:10.1038/376565a0. PMID 7637803. S2CID 4340999.
  16. ^ Leakey, M. G.; et al. (2001). "New hominin genus from eastern Africa shows diverse middle Pliocene lineages". Nature. 410 (6827): 433–440. Bibcode:2001Natur.410..433L. doi:10.1038/35068500. PMID 11260704. S2CID 4409453.
  17. ^ Senut, B.; Pickford, M.; Gommery, D.; Mein, P.; Cheboi, K.; Coppens, Y. (2001). "First hominid from the Miocene (Lukeino Formation, Kenya)". Comptes Rendus de l'Académie des Sciences, Série IIA. 332 (2): 137–144. Bibcode:2001CRASE.332..137S. doi:10.1016/S1251-8050(01)01529-4. S2CID 14235881.
  18. ^ Brunet, M.; Guy, F.; Pilbeam, D.; Mackaye, H. T.; et al. (2002). "A new hominid from the Upper Miocene of Chad, Central Africa" (PDF). Nature. 418 (6894): 145–151. Bibcode:2002Natur.418..145B. doi:10.1038/nature00879. PMID 12110880. S2CID 1316969.
  19. ^ Filler, Aaron G. (October 10, 2007). "Homeotic Evolution in the Mammalia: Diversification of Therian Axial Seriation and the Morphogenetic Basis of Human Origins". PLOS ONE. 2 (10): e1019. Bibcode:2007PLoSO...2.1019F. doi:10.1371/journal.pone.0001019. PMC 2000357. PMID 17925867.
  20. ^ a b McNulty, K. P. (2016). "Hominin Taxonomy and Phylogeny: What's In A Name?". Nature Education Knowledge. 7 (1): 2.
  21. ^ Kimbel, W. H.; Lockwood, C. A.; Ward, C. V.; Leakey, M. G.; Rake, Y.; Johanson, D. C. (2006). "Was Australopithecus anamensis ancestral to A. afarensis? A case of anagenesis in the hominin fossil record". Journal of Human Evolution. 51 (2): 134–152. Bibcode:2006JHumE..51..134K. doi:10.1016/j.jhevol.2006.02.003. PMID 16630646.
  22. ^ Johanson, D. C.; White, T. D. (1979). "A Systematic Assessment of Early African Hominids". Science. 203 (4378): 321–330. Bibcode:1979Sci...203..321J. doi:10.1126/science.104384. PMID 104384.
  23. ^ Tobias, Phillip V. (1980). ""Australopithecus afarensis" and A. africanus: Critique and an alternative hypothesis". Palaeontologia Africana. S2CID 81551249.
  24. ^ Villmoare, B.; Kimbel, W. H.; Seyoum, C.; et al. (2015). "Early Homo at 2.8 Ma from Ledi-Geraru, Afar, Ethiopia". Science. 347 (6228): 1352–1355. Bibcode:2015Sci...347.1352V. doi:10.1126/science.aaa1343. PMID 25739410.
  25. ^ a b Rak, Y.; Ginzburg, A.; Geffen, E. (2007). "Gorilla-like anatomy on Australopithecus afarensis mandibles suggests Au. afarensis link to robust australopiths". Proceedings of the National Academy of Sciences. 104 (16): 6568–6572. Bibcode:2007PNAS..104.6568R. doi:10.1073/pnas.0606454104. PMC 1871826. PMID 17426152.
  26. ^ White, T. D.; Suwa, G.; Asfaw, B. (1994). "Australopithecus ramidus, a new species of early hominid from Aramis, Ethiopia". Nature. 371 (6495): 306–312. Bibcode:1994Natur.371..306W. doi:10.1038/371306a0. PMID 8090200. S2CID 4347140.
  27. ^ Cela-Conde, C. J.; Ayala, F. J. (2003). "Genera of the human lineage". Proceedings of the National Academy of Sciences. 100 (13): 7684–7689. Bibcode:2003PNAS..100.7684C. doi:10.1073/pnas.0832372100. PMC 164648. PMID 12794185.
  28. ^ Bonde, N. (2011). "Hominid Diversity and 'Ancestor' Myths". The Symbolic Species Evolved. Springer Nature. ISBN 978-94-007-2336-8.
  29. ^ Brunet, M.; Beauvilain, A.; Coppens, Y.; Heintz, É.; Moutaye, A. H. E; Pilbeam, D. (1996). "Australopithecus bahrelghazali, une nouvelle espèce d'Hominidé ancien de la région de Koro Toro (Tchad)" (PDF). Comptes Rendus des Séances de l'Académie des Sciences. 322: 907–913.
  30. ^ Haile-Selassie, Y; Gibert, L.; Melillo, S. M.; Ryan, T. M.; Alene, M.; Deino, A.; Levin, N. E.; Scott, G.; Saylor, B. Z. (2015). "New species from Ethiopia further expands Middle Pliocene hominin diversity". Nature. 521 (7553): 483–488. Bibcode:2015Natur.521..483H. doi:10.1038/nature14448. PMID 26017448. S2CID 4455029.
  31. ^ Spoor, F.; Leakey, M. G.; O'Higgins, P. (2016). "Middle Pliocene hominin diversity: Australopithecus deyiremeda and Kenyanthropus platyops". Philosophical Transactions of the Royal Society B. 371 (1698): 20150231. doi:10.1098/rstb.2015.0231. PMC 4920288. PMID 27298462.
  32. ^ Wood, Bernard; K. Boyle, Eve (January 2016). "Hominin taxic diversity: Fact or fantasy?: HOMININ TAXIC DIVERSITY". American Journal of Physical Anthropology. 159 (Suppl 61): 37–78. doi:10.1002/ajpa.22902. PMID 26808110.
  33. ^ Kimbel, W. H.; Yak, Y.; Johanson, D. C. (11 March 2004). "A. L. 444-2: the skull as a whole". The skull of Australopithecus afarensis. Oxford University Press. ISBN 978-0-19-803569-5.
  34. ^ Ward, C. V.; Plavcan, J. M.; Manthi, F. K. (2010). "Anterior dental evolution in the Australopithecus anamensisafarensis lineage". Philosophical Transactions of the Royal Society B. 365 (1556): 3333–3344. doi:10.1098/rstb.2010.0039. PMC 2981954. PMID 20855307.
  35. ^ Teaford, M. F.; Ungar, P. S. (2000). "Diet and the evolution of the earliest human ancestors". Proceedings of the National Academy of Sciences. 97 (25): 13506–13511. Bibcode:2000PNAS...9713506T. doi:10.1073/pnas.260368897. PMC 17605. PMID 11095758.
  36. ^ Gunz, P.; Neubauer, S.; Falk, D.; et al. (2020). "Australopithecus afarensis endocasts suggest ape-like brain organization and prolonged brain growth". Science Advances. 6 (14): eaaz4729. Bibcode:2020SciA....6.4729G. doi:10.1126/sciadv.aaz4729. PMC 7112758. PMID 32270044.
  37. ^ McHenry, H. M. (1991). "Femoral Lengths and Stature in Plio-Pleistocene Hominids". American Journal of Physical Anthropology. 85 (2): 149–158. doi:10.1002/ajpa.1330850204. PMID 1882979.
  38. ^ McHenry, H. M. (1992). "Body Size and Proportions in Early Hominids". American Journal of Physical Anthropology. 87 (4): 407–431. doi:10.1002/ajpa.1330870404. PMID 1580350.
  39. ^ Reno, P. L.; Meindl, R. S.; McCollum, M. A.; Lovejoy, C. O. (2003). "Sexual dimorphism in Australopithecus afarensis was similar to that of modern humans". Proceedings of the National Academy of Sciences. 100 (16): 4404–4409. Bibcode:2003PNAS..100.9404R. doi:10.1073/pnas.1133180100. PMC 170931. PMID 12878734.
  40. ^ Brassey, C. A.; O'Mahoney, T. G.; Chamberlain, A. T.; Sellers, W. I. (2018). "A volumetric technique for fossil body mass estimation applied to Australopithecus afarensis" (PDF). Journal of Human Evolution. 115: 51. Bibcode:2018JHumE.115...47B. doi:10.1016/j.jhevol.2017.07.014. PMID 28838563.
  41. ^ a b c d e f Masao, F. T.; Ichumbaki, E. B.; Cherin, M.; et al. (2016). "New footprints from Laetoli (Tanzania) provide evidence for marked body size variation in early hominins". eLife. 5: e19568. doi:10.7554/eLife.19568. PMC 5156529. PMID 27964778.
  42. ^ Hewitt, G.; MacLarnon, A.; Jones, K. E. (2002). "The Functions of Laryngeal Air Sacs in Primates: A New Hypothesis". Folia Primatologica. 73 (2–3): 70–94. doi:10.1159/000064786. PMID 12207055. S2CID 17329870.
  43. ^ Meyer, M. R. (2015). "The Spinal Cord in Hominin Evolution". eLS: 1–6. doi:10.1002/9780470015902.a0027058. ISBN 9780470015902.
  44. ^ Meyer, M. R.; Williams, S. A.; Smith, M. P.; Sawyer, G. J. (2015). "Lucy's back: Reassessment of fossils associated with the A.L. 288-1 vertebral column". Journal of Human Evolution. 84: 174–180. Bibcode:2015JHumE..85..174M. doi:10.1016/j.jhevol.2015.05.007. PMID 26058822. S2CID 10410978.
  45. ^ Ward, C. V.; Nalley, T. K.; Spoor, F.; Tafforeau, P.; Alemseged, Z. (2017). "Thoracic Vertebral Count and Thoracolumbar Transition in Australopithecus afarensis". Proceedings of the National Academy of Sciences. 114 (23): 6000–6004. Bibcode:2017PNAS..114.6000W. doi:10.1073/pnas.1702229114. PMC 5468642. PMID 28533391.
  46. ^ Arias-Martorell, J.; Potau, J. M.; Bello-Hellegouarch, G.; Pérez-Pérez, A. (2015). "Like Father, Like Son: Assessment of the Morphological Affinities of A.L. 288–1 (A. afarensis), Sts 7 (A. africanus) and Omo 119–73–2718 (Australopithecus sp.) through a Three-Dimensional Shape Analysis of the Shoulder Joint". PLOS ONE. 10 (2): e0117408. Bibcode:2015PLoSO..1017408A. doi:10.1371/journal.pone.0117408. PMC 4317181. PMID 25651542.
  47. ^ a b Green, D. J.; Alemseged, Z. (2012). "Australopithecus afarensis Scapular Ontogeny, Function, and the Role of Climbing in Human Evolution". Science. 338 (6106): 514–517. Bibcode:2012Sci...338..514G. doi:10.1126/science.1227123. PMID 23112331. S2CID 206543814.
  48. ^ Drapeau, M. S. M.; Ward, C. V. (2007). "Forelimb Segment Length Proportions in Extant Hominoids and Australopithecus afarensis". American Journal of Physical Anthropology. 132 (3): 327–343. doi:10.1002/ajpa.20533. PMID 17154362.
  49. ^ Marzke, M. W. (1983). "Joint functions and grips of the Australopithecus afarensis hand, with special reference to the region of the capitate". Journal of Human Evolution. 12 (2): 197–211. Bibcode:1983JHumE..12..197M. doi:10.1016/S0047-2484(83)80025-6.
  50. ^ Domalain, M.; Bertin, A.; Daver, G. (2017). "Was Australopithecus afarensis able to make the Lomekwian stone tools? Towards a realistic biomechanical simulation of hand force capability in fossil hominins and new insights on the role of the fifth digit". Comptes Rendus Palevol. 16 (5–6): 572–584. Bibcode:2017CRPal..16..572D. doi:10.1016/j.crpv.2016.09.003.
  51. ^ a b Gruss, L. T.; Schmitt, D. (2015). "The evolution of the human pelvis: changing adaptations to bipedalism, obstetrics and thermoregulation". Philosophical Transactions of the Royal Society B. 370 (1663): 20140063. doi:10.1098/rstb.2014.0063. PMC 4305164. PMID 25602067.
  52. ^ Rak, Y. (1991). "Lucy's pelvic anatomy: its role in bipedal gait". Journal of Human Evolution. 20 (4): 283–290. Bibcode:1991JHumE..20..283R. doi:10.1016/0047-2484(91)90011-J.
  53. ^ Latimer, B.; Lovejoy, C. O. (1989). "The calcaneus of Australopithecus afarensis and its implications for the evolution of bipedality". American Journal of Physical Anthropology. 78 (3): 369–386. doi:10.1002/ajpa.1330780306. PMID 2929741.
  54. ^ DeSilva, J. M.; Gill, C. M.; Prang, T. C.; et al. (2018). "A nearly complete foot from Dikika, Ethiopia and its implications for the ontogeny and function of Australopithecus afarensis". Science Advances. 4 (7): eaar7723. Bibcode:2018SciA....4.7723D. doi:10.1126/sciadv.aar7723. PMC 6031372. PMID 29978043.
  55. ^ Wynn, J. G.; Sponheimer, M.; Kimbel, W. H.; et al. (2013). "Diet of Australopithecus afarensis from the Pliocene Hadar Formation, Ethiopia". Proceedings of the National Academy of Sciences. 110 (26): 10495–10500. Bibcode:2013PNAS..11010495W. doi:10.1073/pnas.1222559110. PMC 3696813. PMID 23733965.
  56. ^ Ungar, P. (2004). "Dental topography and diets of Australopithecus afarensis and early Homo". Journal of Human Evolution. 46 (5): 605–622. Bibcode:2004JHumE..46..605U. doi:10.1016/j.jhevol.2004.03.004. PMID 15120268.
  57. ^ McPherron, S. P.; Alemseged, Z.; Marean, C. W.; et al. (2010). "Evidence for stone-tool-assisted consumption of animal tissues before 3.39 million years ago at Dikika, Ethiopia". Nature. 466 (7308): 857–860. Bibcode:2010Natur.466..857M. doi:10.1038/nature09248. PMID 20703305. S2CID 4356816.
  58. ^ Domínguez-Rodrigo, M.; Pickering, T. R.; Bunn, H. T. (2010). "Configurational approach to identifying the earliest hominin butchers". Proceedings of the National Academy of Sciences. 107 (49): 20929–20934. Bibcode:2010PNAS..10720929D. doi:10.1073/pnas.1013711107. PMC 3000273. PMID 21078985.
  59. ^ Werner, J. J. (2012). "Mating Behavior in Australopithecus and Early Homo: A Review of the Diagnostic Potential of Dental Dimorphism". University of Western Ontario Journal of Anthropology. 22 (1): 11–19.
  60. ^ Larsen, C. S. (2003). "Equality for the sexes in human evolution? Early hominid sexual dimorphism and implications for mating systems and social behavior". Proceedings of the National Academy of Sciences. 100 (16): 9103–9104. Bibcode:2003PNAS..100.9103L. doi:10.1073/pnas.1633678100. PMC 170877. PMID 12886010.
  61. ^ Reno, P. L.; Lovejoy, C. O. (2015). "From Lucy to Kadanuumuu: balanced analyses of Australopithecus afarensis assemblages confirm only moderate skeletal dimorphism". PeerJ. 3: e925. doi:10.7717/peerj.925. ISSN 2167-8359. PMC 4419524. PMID 25945314.
  62. ^ Lovejoy, C. O. (2009). "Reexamining human origins in light of Ardipithecus ramidus" (PDF). Science. 326 (5949): 74e1–8. Bibcode:2009Sci...326...74L. doi:10.1126/science.1175834. ISSN 1095-9203. PMID 19810200. S2CID 42790876.
  63. ^ DeSilva, J. M.; Laudicina, N. M.; Rosenberg, K. R.; Trevathan, K. R. (2017). "Neonatal Shoulder Width Suggests a Semirotational, Oblique Birth Mechanism in Australopithecus afarensis". The Anatomical Record. 300 (5): 890–899. doi:10.1002/ar.23573. PMID 28406564.
  64. ^ a b c Sellers, W. I.; Cain, G. M.; Wang, W.; Crompton, R. H. (2005). "Stride lengths, speed and energy costs in walking of Australopithecus afarensis: using evolutionary robotics to predict locomotion of early human ancestors". Journal of the Royal Society Interface. 2 (5): 431–441. doi:10.1098/rsif.2005.0060. PMC 1618507. PMID 16849203.
  65. ^ Hatala, K. G.; Demes, B.; Richmond, B. G. (2016). "Laetoli footprints reveal bipedal gait biomechanics different from those of modern humans and chimpanzees". Proceedings of the Royal Society B. 283 (1836): 20160235. doi:10.1098/rspb.2016.0235. PMC 5013756. PMID 27488647.
  66. ^ Cook, D. C.; Buikstra, J. E.; DeRousseau, C. J.; Johanson, D. C. (1983). "Vertebral Pathology in the Afar Australopithecines". American Journal of Physical Anthropology. 60 (1): 83–101. doi:10.1002/ajpa.1330600113. PMID 6408925.
  67. ^ Gibbons, A. (2016). "Did famed human ancestor 'Lucy' fall to her death?". Science. doi:10.1126/science.aah7237.
  68. ^ Charlier, P.; Coppens, Y.; Augias, A.; et al. (2018). "Mudslide and/or animal attack are more plausible causes and circumstances of death for AL 288 ('Lucy'): A forensic anthropology analysis". Medico-Legal Journal. 86 (3): 139–142. doi:10.1177/0025817217749504. PMID 29313437. S2CID 20995655.
  69. ^ Pettitt, P. (2013). The Palaeolithic Origins of Human Burial. Routledge. pp. 44–45. ISBN 978-1-136-69910-8.
  70. ^ Pettitt, P.; Anderson, J. R. (2019). "Primate thanatology and hominoid mortuary archeology". Primates. 61 (1): 10. doi:10.1007/s10329-019-00769-2. PMC 6971134. PMID 31646398.
  71. ^ Reed, K. E.; Rector, A. L. (2006). "African Pliocene Palaeoecology". Evolution of the Human Diet: The Known, the Unknown, and the Unknowable. Oxford University Press. ISBN 978-0-19-534601-5.
  72. ^ Hart, D.; Sussman, R. (2011). "The Influence of Predation on Primate and Early Human Evolution: Impetus for Cooperation". Origins of Altruism and Cooperation. Springer Science and Business Media. pp. 19–40. doi:10.1007/978-1-4419-9520-9_3. ISBN 978-1-4419-9519-3.
  73. ^ Dávid-Barrett, T.; Dunbar, R. I. M. (2016). "Bipedality and hair loss in human evolution revisited: The impact of altitude and activity scheduling". Journal of Human Evolution. 94: 72–82. Bibcode:2016JHumE..94...72D. doi:10.1016/j.jhevol.2016.02.006. PMC 4874949. PMID 27178459.
  74. ^ Raymonde, B.; Potts, R.; Chalie, F.; Jolly, D. (2004). "High-Resolution Vegetation and Climate Change Associated with Pliocene Australopithecus afarensis". Proceedings of the National Academy of Sciences. 101 (33): 12125–12129. Bibcode:2004PNAS..10112125B. doi:10.1073/pnas.0401709101. PMC 514445. PMID 15304655.

Further reading

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  • Kimbel, W. H.; Yak, Y.; Johanson, D. C. (11 March 2004). The skull of Australopithecus afarensis. Oxford University Press. ISBN 978-0-19-803569-5.
  • Rak, Y. (2014). "Australopithecus afarensis". The Australopithecine Face. Academic Press. pp. 66–74. ISBN 978-1-4832-1980-6.
  • Haile-Selassie, Y.; Su, D. F. (2015). The Postcranial Anatomy of Australopithecus afarensis: New Insights from KSD-VP-1/1. Vertebrate Paleobiology and Paleoanthropology. Springer. doi:10.1007/978-94-017-7429-1. ISBN 978-94-017-7429-1. S2CID 133164058.
  • Radice-Wood, J. M. (1987). The Social Organization of Australopithecus afarensis: A Critical Assessment of Monogamy and a Counter Proposal for the Probability of Polygyny. California State University.
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