|Skull of P. boisei (MGL 95211)|
Paranthropus is a genus of extinct hominin which contains two widely accepted species: P. robustus and P. boisei. However, the validity of Paranthropus is contested, and it is sometimes considered to be synonymous with Australopithecus. They are also referred to as the robust australopithecines. They lived between approximately 2.6 and 0.6 million years ago (mya) from the end of the Pliocene to the Middle Pleistocene.
Paranthropus is characterised by robust skulls, with a prominent gorilla-like sagittal crest along the midline–which suggest strong chewing muscles–and broad, herbivorous teeth used for grinding. However, they likely preferred soft food over tough and hard food. Paranthropus species were generalist feeders, but P. robustus was likely an omnivore, whereas P. boisei was likely herbivorous and mainly ate bulbotubers. They were bipeds. Despite their robust heads, they had comparatively small bodies. Average weight and height are estimated to be 40 kg (88 lb) at 132 cm (4 ft) for P. robustus males, 50 kg (110 lb) at 137 cm (4 ft 6 in) for P. boisei males, 32 kg (71 lb) at 110 cm (3 ft 7 in) for P. robustus females, and 34 kg (75 lb) at 124 cm (4 ft 1 in) for P. boisei females.
They were possibly polygamous and patrilocal, but there are no modern analogues for australopithecine societies. They are associated with bone tools and contested as the earliest evidence of fire usage. They typically inhabited woodlands, and coexisted with some early human species, namely A. africanus, H. habilis, and H. erectus. They were preyed upon by the large carnivores of the time, specifically crocodiles, leopards, sabertoothed cats, and hyaenas.
- P. robustus
The genus Paranthropus was first erected by Scottish South African palaeontologist Robert Broom in 1938, with the type species P. robustus.  "Paranthropus" derives from Ancient Greek παρα para beside or alongside; and άνθρωπος ánthropos man.  The type specimen, a male braincase, TM 1517, was discovered by schoolboy Gert Terblanche at the Kromdraai fossil site, about 70 km (43 mi) southwest of Pretoria, South Africa.  By 1988, at least 6 individuals were unearthed in around the same area, now known as the Cradle of Humankind. 
In 1948, at Swartkrans Cave, in about the same vicinity as Kromdraai, Broom and South African palaeontologist John Talbot Robinson described P. crassidens based on a subadult jaw, SK 6. He believed later Paranthropus were morphologically distinct from earlier Paranthropus in the cave—that is, the Swartkrans Paranthropus were reproductively isolated from Kromdraai Paranthropus and the former eventually speciated.  By 1988, several specimens from Swartkrans had been placed into P. crassidens. However, this has since been synonymised with P. robustus as the two populations do not seem to be very distinct. 
- P. boisei
In 1959, P. boisei was discovered by Mary Leakey at Olduvai Gorge, Tanzania (specimen OH 5). Her husband Louis named it Zinjanthropus boisei because he believed it differed greatly from Paranthropus and Australopithecus. The name derives from " Zinj", an ancient Arabic word for the coast of East Africa, and "boisei", referring to their financial benefactor Charles Watson Boise.  However, this genus was rejected at Mr. Leakey's presentation before the 4th Pan-African Congress on Prehistory, as it was based on a single specimen.  The discovery of the Peninj Mandible made the Leakey's reclassify their species as Australopithecus (Zinjanthropus) boisei in 1964,  but in 1967, South African palaeoanthropologist Phillip V. Tobias subsumed it into Australopithecus as A. boisei. However, as more specimens were found, the combination Paranthropus boisei became more popular. 
It is debated whether the wide range of variation in jaw size indicates simply sexual dimorphism or a grounds for identifying a new species. It could be explained as groundmass filling in cracks naturally formed after death, inflating the perceived size of the bone.    P. boisei also has a notably wide range of variation in skull anatomy, but these features likely have no taxonomic bearing. 
- P. aethiopicus
In 1968, French palaeontologists Camille Arambourg and Yves Coppens described "Paraustralopithecus aethiopicus" based on a toothless mandible from the Shungura Formation, Ethiopia (Omo 18).  In 1976, American anthropologist Francis Clark Howell and Breton anthropologist Yves Coppens reclassified it as A. africanus.  In 1986, after the discovery of the skull KNM WT 17000 by English anthropologist Alan Walker and Richard Leakey classified it into Paranthropus as P. aethiopicus.  There is debate whether this is synonymous with P. boisei,  the main argument for separation being the skull seems less adapted for chewing tough vegetation.  
In 1989, palaeoartist and zoologist Walter Ferguson reclassified KNM WT 17000 into a new species, walkeri, because he considered the skull's species designation questionable as it comprised the skull whereas the holotype of P. aethiopicus comprised only the mandible.  Ferguson's classification is almost universally ignored,  and is considered to be synonymous with P. aethiopicus. 
In 1963, while in the Congo, French ethnographer Charles Cordier assigned the name "P. congensis" to a super-strong, monstrous ape-man cryptid called "Kikomba", "Apamándi", "Abanaánji", "Zuluzúgu", or "Tshingómbe" by various native tribes which he heard stories about. 
In 2015, Ethiopian palaeoanthropologist Yohannes Haile-Selassie and colleagues described the 3.5–3.2 Ma A. deyiremeda based on 3 jawbones from the Afar Region, Ethiopia. They noted that, though it shares many similarities with Paranthropus, it may not have been closely related because it lacked enlarged molars which characterize the genus.  Nonetheless, in 2018, independent researcher Johan Nygren recommended moving it to Paranthropus based on dental and presumed dietary similarity. 
In 1951, American anthropologists Sherwood Washburn and Bruce D. Patterson were the first to suggest that Paranthropus should be considered a junior synonym of Australopithecus as the former was only known from fragmentary remains at the time, and dental differences were too minute to serve as justification.  In face of calls for subsumation, Leakey  and Robinson  continued defending its validity. Various other authors were still unsure until more complete remains were found.  Paranthropus is sometimes classified as a subgenus of Australopithecus. 
There is currently no clear consensus on the validity of Paranthropus. The argument rests upon whether the genus is monophyletic—is composed of a common ancestor and all of its descendants—and the argument against monophyly (that the genus is paraphyletic) says that P. robustus and P. boisei evolved similar gorilla-like heads independently of each other by coincidence ( convergent evolution), as chewing adaptations in hominins evolve very rapidly and multiple times at various points in the family tree ( homoplasy).  In 1999, a chimp-like ulna forearm bone was assigned to P. boisei, the first discovered ulna of the species, which was markedly different from P. robustus ulnae, which could suggest paraphyly. 
P. aethiopicus is the earliest member of the genus, with the oldest remains, from the Ethiopian Omo Kibish Formation, dated to 2.6 mya at the end of the Pliocene. It is sometimes regarded as the direct ancestor of P. boisei and P. robustus.  It is possible that P. aethiopicus evolved even earlier, up to 3.3 mya, on the expansive Kenyan floodplains of the time.  The oldest P. boisei remains date to about 2.3 mya from Malema, Malawi.  P. boisei changed remarkably little over its nearly 1 million year existence.  Paranthropus had spread into South Africa by 2 mya with the earliest P. robustus remains.   
It is sometimes suggested that Paranthropus and Homo are sister taxa, both evolving from Australopithecus. This may have occurred during a drying trend 2.8–2.5 mya in the Great Rift Valley, which caused the retreat of woodland environments in favor of open savanna, with forests growing only along rivers and lakes. Homo evolved in the former, and Paranthropus in the latter riparian environment.    However, the classifications of Australopithecus species is problematic. 
Paranthropus had a massively built, tall, and flat skull, with a prominent gorilla-like sagittal crest along the midline which anchored massive temporalis muscles used in chewing.  Like other australopithecines, Paranthropus exhibited sexual dimorphism, with males notably larger than females.    They had large molars with a relatively thick tooth enamel coating ( post-canine megadontia),  and comparatively small incisors (similar in size to modern humans),  possibly adaptations to processing abrasive foods.   The teeth of P. aethiopicus developed faster than those of P. boisei. 
Paranthropus had adaptations to the skull to resist large bite loads while feeding, namely the expansive squamosal sutures.  The notably thick palate was once thought to have been an adaptation to resist a high bite force, but is better explained as a byproduct of facial lengthening and nasal anatomy. 
In P. boisei, the jaw hinge was adapted to grinding food side-to-side (rather than up-and-down in modern humans), which is better at processing the starchy abrasive foods that likely made up the bulk of its diet. P. robustus may have chewed in a front-to-back direction instead, and had less exaggerated (less derived) anatomical features than P. boisei as it perhaps did not require them with this kind of chewing strategy. This may have also allowed P. robustus to better process tougher foods. 
The braincase volume averaged about 500 cm3 (31 in3), comparable to gracile australopithecines, but smaller than Homo.  Modern human brain volume averages 1,270 cm3 (78 in3) for men and 1,130 cm3 (69 in3) for women. 
Unlike P. robustus, the forearms of P. boisei were heavily built, which might suggest habitual suspensory behaviour as in orangutans and gibbons.    A P. boisei shoulder blade indicates long infraspinatus muscles, which is also associated with suspensory behavior.  A P. aethiopicus ulna, on the other hand, shows more similarities to Homo than P. boisei. 
Paranthropus were bipeds, and their hips, legs, and feet resemble A. afarensis and modern humans.   The pelvis is similar to A. afarensis, but the hip joints are smaller in P. robustus. The physical similarity implies a similar walking gait.  Their modern-humanlike big toe indicates a modern-humanlike foot posture and range of motion, but the more distal ankle joint would have inhibited the modern human toe-off gait cycle. By 1.8 mya, Paranthropus and H. habilis may have achieved about the same grade of bipedality. 
In comparison to the large, robust head, the body was rather small. Average weight for P. robustus may have been 40 kg (88 lb) for males and 32 kg (71 lb) for females;  and for P. boisei 50 kg (110 lb) for males and 34 kg (75 lb) for females.  At Swartkrans Cave Members 1 and 2, about 35% of the P. robustus individuals are estimated to have weighed 28 kg (62 lb), 22% about 43 kg (95 lb), and the remaining 43% bigger than the former but less than 54 kg (119 lb). At Member 3, all individuals were about 45 kg (99 lb).  Female weight was about the same in contemporaneous H. erectus, but male H. erectus were on average 13 kg (28.7 lbs) heavier than P. robustus males.  P. robustus sites are oddly dominated by small adults, which could be explained as heightened predation or mortality of the larger males of a group.  The largest known Paranthropus individual was estimated at 54 kg (119 lb). 
According to a 1991 study, based on femur length and using the dimensions of modern humans, male and female P. robustus are estimated to have stood on average 132 and 110 cm (4 ft 4 in and 3 ft 7 in) respectively; and P. boisei 137 and 124 cm (4 ft 6 in and 4 ft 1 in). However, the latter estimates are problematic as there were no positively identified male P. boisei femurs at the time.  In 2013, a 1.34 Ma male P. boisei partial skeleton was estimated to be at least 156 cm (5 ft 1 in) and 50 kg (110 lb). 
Paranthropus seems to have had notably high rates of pitting enamel hypoplasia (PEH), where tooth enamel formation is spotty instead of mostly uniform. In P. robustus, about 47% of baby teeth and 14% of adult teeth were affected, in comparison to about 6.7% and 4.3% respectively in any other tested hominin species. The condition of these holes covering the entire tooth is consistent with the modern human ailment amelogenesis imperfecta. However, since circular holes in enamel coverage are uniform in size, only present on the molar teeth, and have the same severity across individuals, the PEH may have been a genetic condition. It is possible that the coding-DNA concerned with thickening enamel also left them more vulnerable to PEH. 
There have been 10 identified cases of cavities in P. robustus, indicating a rate similar to modern humans. A molar from Drimolen, South Africa, showed a cavity on the tooth root, a rare occurrence in fossil great apes. In order for cavity-creating bacteria to reach this area, the individual would have had to have also presented either alveolar resportion, which is commonly associated with gum disease; or super-eruption of teeth which occurs when teeth become worn down and have to erupt a bit more in order to maintain a proper bite, and this exposed the root. The latter is most likely, and the exposed root seems to have caused hypercementosis to anchor the tooth in place. The cavity seems to have been healing, which may have been caused by a change in diet or mouth microbiome, or the loss of the adjacent molar. 
It was once thought P. boisei cracked open nuts with its powerful teeth, giving OH 5 the nickname "Nutcracker Man". However, like gorillas, Paranthropus likely preferred soft foods, but would consume tough or hard food during leaner times, and the powerful jaws were used only in the latter situation.  In P. boisei, thick enamel was more likely used to resist abrasive gritty particles rather than to minimize chipping while eating hard foods.  In fact, there is a distinct lack of tooth fractures which would have resulted from such activity.  
Paranthropus were generalist feeders, but diet seems to have ranged dramatically with location. The South African P. robustus appears to have been an omnivore, with a diet similar to contemporaneous Homo  and nearly identical to the later H. ergaster,  and subsisted on mainly C4 savanna plants and C3 forest plants, which could indicate either seasonal shifts in diet or seasonal migration from forest to savanna. In leaner times it may have fallen back on brittle food. It likely also consumed seeds   and possibly tubers or termites.  A high cavity rate could indicate honey consumption. 
The East African P. boisei, on the other hand, seems to have been largely herbivorous and fed on C4 plants. Its powerful jaws allowed it to consume a wide variety of different plants,   though it may have largely preferred nutrient-rich bulbotubers as these are known to thrive in the well-watered woodlands it is thought to have inhabited. Feeding on these, P. boisei may have been able to meet its daily caloric requirements of approximately 9700 kJ after about 6 hours of foraging. 
Juvenile P. robustus may have relied more on tubers than adults, given the elevated levels of Strontium compared to adults in teeth from Swartkrans Cave, which, in the area, was most likely sourced from tubers. Dentin exposure on juvenile teeth could indicate early weaning, or a more abrasive diet than adults which wore away the cementum and enamel coatings, or both. It is also possible juveniles were less capable of removing grit from dug-up food rather than purposefully seeking out more abrasive foods. 
Bone tools dating between 2.3 and 0.6 mya have been found in abundance in Swartkrans,  Kromdraai, and Drimolen Caves, and are often associated with P. robustus. Though Homo is also known from these caves, their remains are comparatively scarce to Paranthropus, making Homo-attribution unlikely. The tools also cooccur with Homo-associated Oldawan and possibly Acheulian stone tool industries. The bone tools were typically sourced from the shaft of long bones from medium- to large-sized mammals, but tools made sourced from mandibles, ribs, and horn cores have also been found. Bone tools have also been found at Oldawan Gorge and directly associated with P. boisei, the youngest dating to 1.34 mya, though a great proportion of other bone tools from here have ambiguous attribution. Stone tools from Kromdraai could possibly be attributed to P. robustus, as no Homo have been found there yet. 
The bone tools were not manufactured or purposefully shaped for a task. However, since the bones display no weathering (and were not scavenged randomly), and there is a preference displayed for certain bones, raw materials were likely specifically hand picked. This could indicate a similar cognitive ability to contemporary Stone Age Homo. 
Bone tools may have been used to cut or process vegetation,  or dig up tubers or termites,   The form of P. robustus incisors appear to be intermediate between H. erectus and modern humans, which could indicate less food processing done by the teeth due to preparation with simple tools. 
Burnt bones were also associated with the inhabitants of Swartkrans, which could indicate some of the earliest fire usage.  However, these bones were found in Member 3, where Paranthropus remains are rarer than H. erectus, and it is also possible the bones were burned in a wildfire and washed into the cave as it is known the bones were not burned onsite.  
Given the marked anatomical and physical differences with modern great apes, there may be no modern analogue for australopithecine societies, so comparisons drawn with modern primates will not be entirely accurate.  
Paranthropus had pronounced sexual dimorphism, with males notably larger than females, which is commonly correlated with a male-dominated polygamous society. P. robustus may have had a harem society similar to modern forest-dwelling silverback gorillas, where one male has exclusive breeding rights to a group of females, as male-female size disparity is comparable to gorillas (based on facial dimensions), and younger males were less robust than older males (delayed maturity is also exhibited in gorillas). 
However, if P. robustus preferred a savanna habitat, a multi-male society would have been more productive to better defend the troop from predators in the more exposed environment, much like savanna baboons. Further, among primates, delayed maturity is also exhibited in the rhesus monkey which has a multi-male society, and may not be an accurate indicator of social structure. 
A 2011 Strontium isotope study of P. robustus teeth from the dolomite Sterkfontein Valley found that, like other hominins, but unlike other great apes, P. robustus females were more likely to leave their place of birth ( patrilocal). This also discounts the plausibility of a harem society, which would have resulted in a matrilocal society due to heightened male–male competition. Males did not seem to have ventured very far from the valley, which could either indicate small home ranges, or that they preferred dolomitic landscapes due to perhaps cave abundance or factors related to vegetation growth. 
Dental development seems to have followed about the same timeframe as it does in modern humans and most other hominins, but, since Paranthropus molars are markedly larger, rate of tooth eruption would have been accelerated.   Their life history may have mirrored that of gorillas as they have the same brain volume,  which (depending on the subspecies) reach physical maturity from 12–18 years and have birthing intervals of 40–70 months. 
It is generally thought that Paranthropus preferred to inhabit wooded, riverine landscapes.  The teeth of Paranthropus, H. habilis, and H. erectus are all known from various overlapping beds in East Africa, such as at Olduvai Gorge  and the Turkana Basin.  P. robustus and H. erectus also appear to have coexisted.  
P. boisei, known from the Great Rift Valley, may have typically inhabited wetlands along lakes and rivers, wooded or arid shrublands, and semiarid woodlands,  though their presence in the savanna-dominated Malawian Chiwondo Beds implies they could tolerate a range of habitats.  During the Pleistocene, there seems to have been coastal and montane forests in Eastern Africa. More expansive river valleys–namely the Omo River Valley–may have served as important refuges for forest-dwelling creatures. Being cut off from the forests of Central Africa by a savanna corridor, these East African forests would have promoted high rates of endemism, especially during times of climatic volatility. 
The Cradle of Humankind, the only area P. robustus is known from, was mainly dominated by the springbok Antidorcas recki, but other antelope, giraffes, and elephants were also seemingly abundant megafauna. Other known primates are early Homo, the Hamadryas baboon, and the extinct colobine monkey Cercopithecoides williamsi. 
The left foot of a P. boisei specimen (though perhaps actually belonging to H. habilis) from Olduvai Gorge seems to have been bitten off by a crocodile,  possibly Crocodylus anthropophagus,  and another's leg shows evidence of leopard predation.  Other likely Olduvan predators of great apes include the hunting hyaena Chasmaporthetes nitidula, and the sabertoothed cats Dinofelis and Megantereon.  The carnivore assemblage at the Cradle of Humankind comprises the two sabertooths, and the hyaena Lycyaenops silberbergi. 
Male P. robustus appear to have had a higher mortality rate than females. It is possible that males were more likely to be kicked out of a group, and these lone males had a higher risk of predation. 
It was once thought that Paranthropus had become a specialist feeder, and were inferior to the more adaptable tool-producing Homo, leading to their extinction, but this has been called into question.      However, smaller brain size may have been a factor in their extinction along with gracile australopithecines.  P. boisei may have died out due to an arid trend starting 1.45 mya, causing the retreat of woodlands, and more competition with savanna baboons and Homo for alternative food resources. 
South African Paranthropus appear to have outlasted their East African counterparts.  The youngest record of P. boisei comes from Konso, Ethiopia about 1.4 mya, however there are no East African sites dated between 1.4 and 1 mya, so it may have persisted until 1 mya.  P. robustus, on the other hand, was recorded in Swartkrans until Member 3 dated to 1–0.6 mya (the Middle Pleistocene), though more likely the younger side of the estimate. 
- Broom, R. (1938). "The Pleistocene Anthropoid Apes of South Africa". Nature. 142 (3591): 377–379. Bibcode: 1938Natur.142..377B. doi: 10.1038/142377a0.
- "Paranthropus". Merriam–Webster Dictionary. Retrieved 19 December 2019.
- Constantino, P. J.; Wood, B. A. (2004). "Paranthropus Paleobiology". Miscelanea en Homenaje a Emiliano Aguirre. Paleoantropologia. III. Museo Arqueológico Regional.
- Broom, R. (1948). "Another new type of fossil ape-man". Nature. 162 (4132): 57. doi: 10.1038/163057a0. PMID 18106151. S2CID 4126221.
- Leakey, L. (1959). "A New Fossil Skull from Olduvai". Nature. 184 (4685): 491–493. Bibcode: 1959Natur.184..491L. doi: 10.1038/184491a0. S2CID 4217460.
- Morell, V. (2011). Ancestral Passions: The Leakey Family and the Quest for Humankind's Beginnings. Touchstone. p. 193. ISBN 978-1-4391-4387-2.
- Leakey, L. S. B.; Leakey, M. B. (1964). "Recent discoveries of fossil hominidsin Tanganyika, at Olduvai and near Lake Natron". Nature. 202 (4927): 5–7. Bibcode: 1964Natur.202....5L. doi: 10.1038/202005a0. PMID 14166721. S2CID 4162123.
- Wood, B. (2005). "A tale of two taxa". Transactions of the Royal Society of South Africa. 60 (2): 91–94. doi: 10.1080/00359190509520483. S2CID 83659439.
- Silverman, N.; Richmond, B.; Wood, B. (2001). "Testing the taxonomic integrity of Paranthropus boisei sensu stricto". American Journal of Physical Anthropology. 115 (2): 167–178. doi: 10.1002/ajpa.1066. PMID 11385603.
- Constantino, P. J.; Wood, B. A. (2007). "The Evolution of Zinjanthropus boisei". Evolutionary Anthropology. 16 (2): 49–62. doi: 10.1002/evan.20130. S2CID 53574805.
- Wood, B.; Constantino, J. (2007). "Paranthropus boisei: Fifty Years of Evidence and Analysis". Yearbook of Physical Anthropology. 50: 106–132. doi: 10.1002/ajpa.20732. PMID 18046746.
- Wood, B.; Lieberman, D. (2001). "Craniodental variation in Paranthropus boisei: a developmental and functional perspective" (PDF). American Journal of Physical Anthropology. 116 (1): 13–25. doi: 10.1002/ajpa.1097. PMID 11536113.
- Arambourg, C.; Coppens, Y. (1968). "Sur la decouverte dans le Pleistocene inferieur de la valle de l'Omo (Ethiopie) d'une mandibule d'Australopithecien" [On the discovery in the Lower Pleistocene Omo Valley (Ethiopia) of an Australopithecine Mandible]. Comptes Rendus des Séances de l'Académie des Sciences (in French). 265: 589–590.
- Ferguson, W. W. (1989). "A New Species of the Genus Australopithecus (Primates: Hominidae) from Plio/Pleistocene Deposits West of Lake Turkana in Kenya". Primates. 30 (2): 223–232. doi: 10.1007/BF02381307. S2CID 28642451.
- Walker, A.; Leakey, R. E.; Harris, J. M.; Brown, F. H. (1986). "2.5-Myr Australopithecus boisei from west of Lake Turkana, Kenya". Nature. 322 (6079): 517–522. Bibcode: 1986Natur.322..517W. doi: 10.1038/322517a0. S2CID 4270200.
- Wood, B.; Richmond, B. G. (2000). "Human evolution: taxonomy and paleobiology". Journal of Anatomy. 192: 34–38. doi: 10.1046/j.1469-7580.2000.19710019.x. PMC 1468107. PMID 10999270.
- Wood, B. (2011). Wiley-Blackwell Encyclopedia of Human Evolution. John Wiley & Sons. pp. 298–299. ISBN 978-1-4443-4247-5.
- Leakey, R.; Lewin, R. (1993). Origins Reconsidered: In Search of what Makes Us Human. Anchor Books. pp. 132–133. ISBN 978-0-385-46792-6.
- Cordier, C. (1963). "Deux anthropoïdes inconnus marchant debout au Congo ex-Belge" [Two unknown, upright-walking anthropoids in the ex-Belgian Congo]. Genus (in French). 19 (1/4): 175–182. JSTOR 29787553.
- Haile-Selassie, Y.; Gilbert, L.; Melillo, S. M.; et al. (2015). "New species from Ethiopia further expands Middle Pliocene hominin diversity" (PDF). Nature. 521 (14448): 483–488. Bibcode: 2015Natur.521..483H. doi: 10.1038/nature14448. PMID 26017448. S2CID 4455029.
- Nygren, J. (2018). "The speciation of Australopithecus and Paranthropus was caused by introgression from the Gorilla lineage" (PDF). PeerJ Preprints. 6: e27130v3. arXiv: 1808.06307. Bibcode: 2018arXiv180806307N. doi: 10.7287/peerj.preprints.27130v3. S2CID 52054499.
- Washburn, S. L.; Patterson, B. D. (1951). "Evolutionary Importance of the South African 'Man-apes'". Nature. 167 (4251): 650–651. Bibcode: 1951Natur.167..650W. doi: 10.1038/167650a0. PMID 14826894. S2CID 4207075.
- Robinson, J. T. (1965). "Homo 'habilis' and the Australopithecines". Nature. 205 (4967): 121–124. Bibcode: 1965Natur.205..121R. doi: 10.1038/205121a0. S2CID 4196031.
- 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.
- McHenry, H. M.; Brown, C. C.; McHenry, L. J. (2007). "Fossil hominin ulnae and the forelimb of Paranthropus". American Journal of Physical Anthropology. 134 (2): 209–218. doi: 10.1002/ajpa.20656. PMID 17596856.
- Joordens, J. C. A.; Feibel, C. S.; Vonhof, H. B.; Schulp, A. S.; Kroon, D. (2019). "Relevance of the eastern African coastal forest for early hominin biogeography". Journal of Human Evolution. 131: 176–202. doi: 10.1016/j.jhevol.2019.03.012. PMID 31182201.
- Wood, B.; Wood, C.; Konigsberg, L. (1994). "Paranthropus boisei: an example of evolutionary stasis?". American Journal of Physical Anthropology. 95 (2): 117–136. doi: 10.1002/ajpa.1330950202. PMID 7802091.
- Stammers, R. C.; Caruana, M.; Herries, A. I. R. (2018). "The first bone tools from Kromdraai and stone tools from Drimolen, and the place of bone tools in the South African Earlier Stone Age". Quaternary International. 495: 87–101. Bibcode: 2018QuInt.495...87S. doi: 10.1016/j.quaint.2018.04.026.
- Herries, A. I. R.; Curnoe, D.; Adams, J. W. (2009). "A multi-disciplinary seriation of early Homo and Paranthropus bearing palaeocaves in southern Africa". Quaternary International. 202 (1–2): 14–28. Bibcode: 2009QuInt.202...14H. doi: 10.1016/j.quaint.2008.05.017.
- Kullmer, O.; Sandrock, O.; Schrenk, F.; Bromage, T. G. (1999). "The Malawi Rift: Biogeography, Ecology and Coexistence of Homo and Paranthropus". Anthropologie. 37 (3): 221–231. JSTOR 26294888.
- Bobe, R.; Behrensmeyer, A. K.; Chapman, R. E. (2002). "Faunal change, environmental variability and late Pliocene hominin evolution". Journal of Human Evolution. 42 (4): 475–497. doi: 10.1006/jhev.2001.0535. PMID 11908957. S2CID 26032638.
- Parins-Fukuchi, C.; Greiner, E.; MacLatchy, L. M.; Fisher, D. C. (2019). "Phylogeny, ancestors and anagenesis in the hominin fossil record" (PDF). Paleobiology. 45 (2): 378–393. doi: 10.1017/pab.2019.12. S2CID 196659329.
- Wood, B.; Strait, D. (2004). "Patterns of resource use in early Homo and Paranthropus". Journal of Human Evolution. 46 (2): 119–162. doi: 10.1016/j.jhevol.2003.11.004. PMID 14871560.
- McHenry, H. M. (1991). "Petite bodies of the "robust" australopithecines". American Journal of Physical Anthropology. 86 (4): 445–454. doi: 10.1002/ajpa.1330860402.
- 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.
- Olejniczak, A. J.; Smith, T. M.; Skinner, M. M.; et al. (2008). "Three-dimensional molar enamel distribution and thickness in Australopithecus and Paranthropus". Biology Letters. 4 (4): 406–410. doi: 10.1098/rsbl.2008.0223. PMC 2610159. PMID 18522924.
- Ungar, P. S.; Grine, F. E. (1991). "Incisor size and wear in Australopithecus africanus and Paranthropus robustus". Journal of Human Evolution. 20 (4): 313–340. doi: 10.1016/0047-2484(91)90013-L.
- Williams, F. L. (2015). "Dietary proclivities of Paranthropus robustus from Swartkrans, South Africa". Anthropological Review. 78 (1): 1–19. doi: 10.1515/anre-2015-0001.
- Wood, B.; Schroer, K. (2012). "Reconstructing the Diet of an Extinct Hominin Taxon: The Role of Extant Primate Models". International Journal of Primatology. 33 (3): 716–742. doi: 10.1007/s10764-012-9602-7. S2CID 15983306.
- Ramirez-Rozzi, F. V. (1993). "Tooth development in East African Paranthropus". Journal of Human Evolution. 24 (6): 429–454. doi: 10.1006/jhev.1993.1030.
- Dzialo, C.; Wood, S. A.; Berthaume, M.; et al. (2013). "Functional implications of squamosal suture size in Paranthropus boisei". American Journal of Physical Anthropology. 153 (2): 260–268. doi: 10.1002/ajpa.22427. PMID 24242913.
- McCollum, M. A. (1998). "Palatal thickening and facial form in Paranthropus: Examination of alternative developmental models". American Journal of Physical Anthropology. 103 (3): 375–392. doi: 10.1002/(SICI)1096-8644(199707)103:3<375::AID-AJPA7>3.0.CO;2-P. PMID 9261500.
- Kupczik, K.; Toro-Ibacache, V.; Macho, G. A. (2018). "On the relationship between maxillary molar root shape and jaw kinematics in Australopithecus africanus and Paranthropus robustus". Royal Society Open Science. 5 (8): 180825. Bibcode: 2018RSOS....580825K. doi: 10.1098/rsos.180825. PMC 6124107. PMID 30225074.
- Du, A.; Zipkin, A. M.; Hatala, K. G.; et al. (2018). "Pattern and process in hominin brain size evolution are scale-dependent". Proceedings of the Royal Society B. 285 (1873): 20172738. doi: 10.1098/rspb.2017.2738. PMC 5832710. PMID 29467267.
- Allen, J. S.; Damasio, H.; Grabowski, T. J. (2002). "Normal neuroanatomical variation in the human brain: an MRI-volumetric study". American Journal of Physical Anthropology. 118 (4): 341–358. doi: 10.1002/ajpa.10092. PMID 12124914. S2CID 21705705.
- Domínguez-Rodrigo, M.; Rayne, T. R.; Baquedano, E.; et al. (2013). "First Partial Skeleton of a 1.34-Million-Year-Old Paranthropus boisei from Bed II, Olduvai Gorge, Tanzania". PLOS ONE. 8 (12): e80347. Bibcode: 2013PLoSO...880347D. doi: 10.1371/journal.pone.0080347. PMC 3855051. PMID 24339873.
- Lague, M. R.; Chirchir, H.; Green, D. J.; Mbua, E. (2019). "Humeral anatomy of the KNM-ER 47000 upper limb skeleton from Ileret, Kenya: Implications for taxonomic identification". Journal of Human Evolution. 126: 24–38. doi: 10.1016/j.jhevol.2018.06.011. PMID 30583842.
- Green, D. J.; Chirchir, H.; Mbua, E. (2018). "Scapular anatomy of Paranthropus boisei from Ileret, Kenya". Journal of Human Evolution. 125: 181–192. doi: 10.1016/j.jhevol.2017.06.013. PMID 30502893.
- Wood B, Richmond BG (July 2000). "Human evolution: taxonomy and paleobiology". Journal of Anatomy. 197 (1): 19–60. doi: 10.1046/j.1469-7580.2000.19710019.x. PMC 1468107. PMID 10999270.
- Ryan, T. M.; Carlson, K. J.; Gordon, A. D.; et al. (2018). "Human-like hip joint loading in Australopithecus africanus and Paranthropus robustus". Journal of Human Anthropology. 121: 12–24. doi: 10.1016/j.jhevol.2018.03.008. PMID 29706230.
- Macchiarelli R, Bondioli L, Galichon V, Tobias PV (February 1999). "Hip bone trabecular architecture shows uniquely distinctive locomotor behaviour in South African australopithecines". Journal of Human Evolution. 36 (2): 211–32. doi: 10.1006/jhev.1998.0267. PMID 10068067.
- Susman, R. L.; Brain, T. M. (1988). "New first metatarsal (SKX 5017) from Swartkrans and the gait of Paranthropus robustus". American Journal of Physical Anthropology. 77 (1): 7–15. doi: 10.1002/ajpa.1330770103. PMID 3189526.
- Susman, R. L.; de Ruiter, D.; Brain, C. K. (2001). "Recently identified postcranial remains of Paranthropus and Early Homo from Swartkrans Cave, South Africa". Journal of Human Evolution. 41 (6): 607–629. doi: 10.1006/jhev.2001.0510. PMID 11782111. S2CID 26326715.
- Braga, J.; Thackeray, J. F.; Bruxelles, L.; Dumoncel, J.; Fourvel, J.-P. (2017). "Stretching the time span of hominin evolution at Kromdraai (Gauteng, South Africa): Recent discoveries". Comptes Rendus Palevol. 16 (1): 58–70. doi: 10.1016/j.crpv.2016.03.003.
- Towle, I.; Irish, J. D. (2019). "A probable genetic origin for pitting enamel hypoplasia on the molars of Paranthropus robustus" (PDF). Journal of Human Evolution. 129: 54–61. doi: 10.1016/j.jhevol.2019.01.002. PMID 30904040.
- Towle, I.; Riga, A.; Irish, J. D.; et al. (2019). "Root caries on a Paranthropus robustus third molar from Drimolen" (PDF). American Journal of Physical Anthropology. 170 (2): 319–323. doi: 10.1002/ajpa.23891. PMID 31265762.
- Ungar, P. S.; Grine, F. E.; Teaford, M. F. (2008). "Dental Microwear and Diet of the Plio-Pleistocene Hominin Paranthropus boisei". PLOS ONE. 3 (4): e2044. Bibcode: 2008PLoSO...3.2044U. doi: 10.1371/journal.pone.0002044. PMC 2315797. PMID 18446200.
- Rabenold, D.; Pearson, O. M. (2011). "Abrasive, Silica Phytoliths and the Evolution of Thick Molar Enamel in Primates, with Implications for the Diet of Paranthropus boisei". PLOS ONE. 6 (12): e28379. Bibcode: 2011PLoSO...628379R. doi: 10.1371/journal.pone.0028379. PMC 3233556. PMID 22163299.
- Towle, Ian; Irish, Joel D.; Groote, Isabelle De (2017). "Behavioral inferences from the high levels of dental chipping in Homo naledi" (PDF). American Journal of Physical Anthropology. 164 (1): 184–192. doi: 10.1002/ajpa.23250. ISSN 1096-8644. PMID 28542710.
- Sponheimer, M.; Lee-Thorp, J.; De Ruiter, D.; Codron, D.; Codron, J.; Baugh, A. T.; Thackeray, F. (2005). "Hominins, sedges, and termites: new carbon isotope data from the Sterkfontein valley and Kruger National Park". Journal of Human Evolution. 48 (3): 301–312. CiteSeerX 10.1.1.421.8468. doi: 10.1016/j.jhevol.2004.11.008. PMID 15737395.
- Lee-Thorp, J.; Thackeray, J. F.; der Merwe, N. V. (2000). "The hunters and the hunted revisited". Journal of Human Evolution. 39 (6): 565–576. doi: 10.1006/jhev.2000.0436. PMID 11102267.
- Sponheimer, M.; Passey, B. H.; de Ruiter, D. J.; et al. (2006). "Isotopic Evidence for Dietary Variability in the Early Hominin Paranthropus robustus". Science. 314 (5801): 980–982. Bibcode: 2006Sci...314..980S. doi: 10.1126/science.1133827. PMID 17095699. S2CID 22291574.
- Constantino, P. J.; Borrero-Lopez, O.; Lawn, B. R. (2018). "Mechanisms of Tooth Damage in Paranthropus Dietary Reconstruction". Biosurface and Biotribology. 4 (3): 73–78. doi: 10.1049/bsbt.2018.0017.
- Backwell, L. R.; d'Errico, F. (2001). "Evidence of termite foraging by Swartkrans early hominids". Proceedings of the National Academy of Sciences. 98 (4): 1358–1363. doi: 10.1073/pnas.021551598. PMC 29261. PMID 11171955.
- Cerling, T. E.; Mbua, E.; Kirera, F. M.; et al. (2011). "Diet of Paranthropus boisei in the early Pleistocene of East Africa". Proceedings of the National Academy of Sciences of the United States of America. 108 (23): 9337–41. Bibcode: 2011PNAS..108.9337C. doi: 10.1073/pnas.1104627108. PMC 3111323. PMID 21536914.
- Macho, G. M. (2014). "Baboon Feeding Ecology Informs the Dietary Niche of Paranthropus boisei". PLOS ONE. 9 (1): e84942. Bibcode: 2014PLoSO...984942M. doi: 10.1371/journal.pone.0084942. PMC 3885648. PMID 24416315.
- Susman, R. L. (1988). "Hand of Paranthropus robustus from Member 1, Swartkrans: fossil evidence for tool behavior". Science. 240 (4853): 781–784. Bibcode: 1988Sci...240..781S. doi: 10.1126/science.3129783. PMID 3129783.
- Brain, C. K.; Sillent, A. (1988). "Evidence from the Swartkrans cave for the earliest use of fire". Nature. 336 (6198): 464–466. Bibcode: 1988Natur.336..464B. doi: 10.1038/336464a0. S2CID 4318364.
- Pickering, T. R. (2012). "What's new is old: comments on (more) archaeological evidence of one-million-year-old fire from South Africa". South African Journal of Science. 108 (5–6): 1–2. doi: 10.4102/sajs.v108i5/6.1250.
- Gowlett, J. A. J.; Wrangham, R. W. (2013). "Earliest fire in Africa: towards the convergence of archaeological evidence and the cooking hypothesis". Azania: Archaeological Research in Africa. 48 (1): 16–17. doi: 10.1080/0067270X.2012.756754. S2CID 163033909.
- Copeland, S. R.; Sponheimmer, M.; de Ruiter, D. J.; Lee-Thorp, J. (2011). "Strontium isotope evidence for landscape use by early hominins". Nature. 474 (7349): 76–78. doi: 10.1038/nature10149. PMID 21637256. S2CID 205225222.
- Kaszycka, K. A. (2016). "Australopithecus robustus societies - one-male or multimale?". South African Journal of Science. 112 (1–2): 124–131. doi: 10.17159/sajs.2016/20150165.
- Lockwood, C. A.; Menter, C. G.; Moggi-Cecchi, J.; Keyser, A. W. (2007). "Extended male growth in a fossil hominin species". Science. 318 (5855): 1443–1446. Bibcode: 2007Sci...318.1443L. doi: 10.1126/science.1149211. PMID 18048687. S2CID 32900905.
- Dean, M. C. (1985). "The eruption pattern of the permanent incisors and first permanent molars in Australopithecus (Paranthropus) robustus". American Journal of Physical Anthropology. 67 (3): 251–257. doi: 10.1002/ajpa.1330670310. PMID 3933358.
- Kelley, J.; Schwartz, G. T. (2012). "Life-History Inference in the Early Hominins Australopithecus and Paranthropus". International Journal of Primatology. 33 (6): 1332–1363. doi: 10.1007/s10764-012-9607-2. S2CID 16288970.
- Robbins, M. M.; Robbins, A. M. (2018). "Variation in the social organization of gorillas: Life history and socioecological perspectives" (PDF). Evolutionary Anthropology. 27 (5): 218–233. doi: 10.1002/evan.21721. PMID 30325554. S2CID 53100488.
- Clarke, R. J. (2012). "A Homo habilis maxilla and other newly-discovered hominid fossils from Olduvai Gorge, Tanzania". Journal of Human Evolution. 63 (2): 418–428. doi: 10.1016/j.jhevol.2011.11.007. PMID 22561056.
- Bocherens, H.; Sandrock, O.; Kullmer, O.; Schrenk, F. (2011). "Hominin palaeoecology in late Pliocene Malawi: first insights from isotopes (13C, 18O) in mammal teeth". South African Journal of Science. 107 (3–4): 1–6. doi: 10.4102/sajs.v107i3/4.331.
- Bobe, R. (2006). "The evolution of arid ecosystems in eastern Africa". Journal of Arid Environments. 66 (3): 564–584. Bibcode: 2006JArEn..66..564B. doi: 10.1016/j.jaridenv.2006.01.010.
- Adams, J. W.; Rovinsky, D. S.; Herries, A. I. R.; Menter, C. G. (2016). "Macromammalian faunas, biochronology and palaeoecology of the early Pleistocene Main Quarry hominin-bearing deposits of the Drimolen Palaeocave System, South Africa". PeerJ. 4: e1941. doi: 10.7717/peerj.1941. PMC 4841245. PMID 27114884.
- Njau, J. K.; Blumenschine, R. J. (2012). "Crocodylian and mammalian carnivore feeding traces on hominid fossils from FLK 22 and FLK NN 3, Plio-Pleistocene, Olduvai Gorge, Tanzania". Journal of Human Evolution. 63 (2): 408–417. doi: 10.1016/j.jhevol.2011.05.008. PMID 21937084.
- Brochu, C. A.; Njau, J.; Blumenschine, R. J.; Densmore, L. D. (2010). "A New Horned Crocodile from the Plio-Pleistocene Hominid Sites at Olduvai Gorge, Tanzania". PLOS ONE. 5 (2): e9333. Bibcode: 2010PLoSO...5.9333B. doi: 10.1371/journal.pone.0009333. PMC 2827537. PMID 20195356.
- Grine, F. E. (2007). Evolutionary History of the Robust Australopithecines. Transaction Publishers. ISBN 978-0-202-36596-1.
- Wood, Bernard; Williams, Alexis (2020). "Meet Your Exotic, Extinct Close Relative: For a million years our likely ancestors in eastern Africa lived alongside creatures so peculiar that scientists today still struggle to make sense of them". American Scientist. 108 (6): 348. doi: 10.1511/2020.108.6.348.
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