Tag Archives: MillionYearOld

Unlocking Australia’s Ancient Past: Study Reveals 230 Million-Year-Old Dinosaur Footprints as the Oldest in the Country

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Unearthed in 1958 by a young fossil hunter in Albion, Brisbane, Queensland, Australia, dinosaur footprints have been officially recognized as the continent’s oldest, dating back approximately 230 million years to the late Triassic period. This discovery indicates that dinosaurs inhabited the Brisbane region far earlier than previously thought by paleontologists.

Living fossils unearthed from Petrie Quarry, Albion, Brisbane, Queensland, Australia. Image credit: Anthony Romilio & Bruce Runnegar, doi: 10.1080/03115518.2025.2607630.

The 18.5 cm (7 in.) long dinosaur footprint was discovered at Petrie’s Quarry, part of the Aspley Formation, alongside a slab featuring narrow linear grooves interpreted as possible tail traces.

Both specimens were extracted before the quarry site was redeveloped, passing through several university collections since then.

“This is the only dinosaur fossil discovered in an Australian capital, highlighting how significant finds can remain hidden in plain sight,” stated Dr. Anthony Romilio, a palaeontologist from the University of Queensland.

“Urban development has rendered the original site inaccessible, leaving behind these footprints as the only evidence of dinosaurs in the area.”

The footprints show impressions of three forward-facing toes, with the central toe demonstrating a faint fan-shaped outline, characteristics typical of a bipedal dinosaur.

Advanced 3D modeling and morphometric analysis revealed that this footprint closely resembles the Ichnogenus Evazoum, commonly linked to early sauropod dinosaurs found elsewhere.

Based on the dimensions of the footprints, Dr. Romilio and Professor Bruce Rannegar estimated that the corresponding dinosaur stood about 78 centimeters (31 inches) tall at the waist and weighed around 144 kilograms (89 pounds).

Utilizing established scaling equations, researchers calculated the maximum potential running speed to be about 60 km/h (37 mph).

While no dinosaur skeletons have been found in the Aspley Formation, these footprints serve as the only direct evidence of dinosaur presence in this time and place.

“Dinosaurs may have walked along waterways, leaving their tracks preserved in sandstone that was later cut to build structures across Brisbane,” Dr. Romilio explained.

“If not for the foresight to conserve this material, the history of Brisbane’s dinosaurs would have remained completely unknown.”

“These footprints were made in sediment by large animals and exemplify a unique kind of trace fossil,” stated Professor Rannegar.

The associated tail print, approximately 13 centimeters (5 inches) long, aligns with structures interpreted as a dinosaur’s tail track. However, the authors caution that without preservation of the corresponding footprint in an appropriate location, its origin remains uncertain.

“The shallow linear grooves found in the tail block closely match reported tail drag traces, yet lack any remaining evidence of Manus or Pes. Their true identity remains ambiguous,” they noted.

“These grooves could have resulted from caudal contact in the orbits of prosauropods, but typically on-site and near the midline of such orbit, which isn’t applicable in this case.”

The team’s research paper has been published this week in The Alcheringa, Australian Journal of Paleontology.

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Anthony Romilio and Bruce Rannegar. Australia’s oldest dinosaur: Reproductive fossils unearthed from the Carnian Aspley Formation in Brisbane, Queensland, Australia. Alcheringa published online on February 1, 2026. doi: 10.1080/03115518.2025.2607630

Source: www.sci.news

2.6 Million-Year-Old Ethiopian Fossil Reveals Widespread Existence of Paranthropus Hominid

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The recently unearthed fossil represents the first known partial specimen of a 2.6-million-year-old lower jaw from Ethiopia’s Afar region, specifically belonging to the genus Paranthropus. This fossil is among the oldest remains found in the region and is likely the earliest of its kind across Africa. This groundbreaking discovery significantly reshapes paleoanthropologists’ perspectives on early hominid evolution, suggesting that these ancient relatives had a more extensive and adaptable lineage than previously recognized.

Paranthropus boisei. Image credit: © Roman Yevseyev.

The newly labeled fossil, MLP-3000, was discovered in the Mille Logia research area and comprises an edentulous mandibular body, complete with preserved roots and a partial molar crown.

Geological and magnetostratigraphic analyses indicate that these fossils date back approximately 2.9 to 2.5 million years during a period marked by dramatic environmental shifts in eastern Africa.

“To understand our evolutionary trajectory as a genus and species, we must also comprehend the ecological and competitive factors that influenced our evolution,” said Zeresenai Alemseged, a professor at the University of Chicago.

“This discovery offers more than just a snapshot; it sheds new light on the underlying forces driving the evolution of Paranthropus.

Until now, Paranthropus fossils had primarily been documented from southern Ethiopia to South Africa, with no prior findings in the Afar region. This lack of evidence was confounding given the region’s abundance of fossils spanning around 6 million years, including significant discoveries of Australopithecus and early homo.

Recent findings reveal that Paranthropus, from its earliest known existence, had a broader geographic range than previously understood.

“We seek to comprehend who we are and how we evolved, influencing our behavior and the environment around us,” Professor Alemseged stated.

“The fossil record showcases more than 15 hominin species, typically classified into four categories: facultative bipeds, habitual bipeds, obligate bipeds, and obligate hominids.”

“Numerous fossils belonging to more than a dozen species, including Ardipithecus, Australopithecus, and homo, have been discovered in the Afar region of northern Ethiopia. The lack of Paranthropus fossils in this area was striking and perplexing for paleoanthropologists, many of whom theorized that this genus never expanded that far north.”

“Some experts have posited that dietary specialization may have restricted Paranthropus, suggesting that competition with more adaptable homo species limited its range,” he added.

“However, this assumption is incorrect; Paranthropus was as adaptable and versatile as homo, and this discovery illustrates that its absence in the Afar area was merely a result of the fossil record.”

According to anatomical analysis, the jaw exhibits a unique blend of features, showcasing characteristics of Paranthropus alongside those found in more primitive hominids, including a notably robust mandibular body and exceptionally large posterior canines.

This mosaic of traits leads researchers to tentatively classify the fossil as Paranthropus sp., without assigning it to a specific species.

The context of this discovery is equally vital as the fossil itself.

The Mille Rogia area preserves sediments from a time of significant environmental change, roughly between 3 million and 2.4 million years ago, during which the climate shifted toward more open grasslands, becoming the dominant habitat.

Fossils of associated animal species highlight these habitat transformations; Paranthropus was not confined to a narrow ecological niche but could thrive in various environments.

The presence of Paranthropus in the Afar region additionally suggests that multiple hominin lineages coexisted in this area during the late Pliocene.

Fossils of early homo and Australopithecus, dating to a similar period, have already been located at nearby archaeological sites, indicating a surprising level of diversity in early homo evolution.

By extending the known range of Paranthropus over 1,000 km north of its previously recognized boundaries, this discovery challenges long-held assumptions regarding the ecology and migration patterns of early hominids.

“This new finding enhances our understanding of adaptation and behavior, including the competitive dynamics between species, diet, physical adaptations, and potential use of stone tools,” Professor Alemseged remarked.

“Discoveries like this spark intriguing questions that prompt us to examine, revise, and formulate new hypotheses about the significant differences among major hominin groups.”

This important finding has been detailed in the following article: paper, published in today’s edition of Nature.

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Zeresenai Alemseged et al.. First long-distance Paranthropus fossils expand the distribution of this adaptable genus. Nature published online on January 21, 2026. doi: 10.1038/s41586-025-09826-x

Source: www.sci.news

7 Million-Year-Old Sahelanthropus Fossil: The Oldest Evidence of Bipedalism

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For over 20 years, Sahelanthropus tchadensis, one of the earliest hominid species (dating back 6.7 to 7.2 million years), was discovered in Chad in 2001. This species is central to a heated debate: Did our earliest ancestors walk upright? A groundbreaking study by paleoanthropologists at New York University provides compelling evidence supporting this notion. The research indicates that Sahelanthropus tchadensis, an ape-like ancestor from Africa, showcases some of the earliest adaptations for bipedal terrestrial locomotion.

Reconstruction of Sahelanthropus tchadensis. Image credit: University of Silesia.

According to New York University, “Sahelanthropus tchadensis was essentially a bipedal ape with a brain size similar to that of a chimpanzee, likely spending considerable time foraging and finding safety in trees,” as noted by Dr. Scott Williams.

“Despite its ape-like appearance, Sahelanthropus tchadensis demonstrated adaptations for bipedal posture and movement on land,” Dr. Williams added.

The team focused on the femur and two partial forearm bones found at the Toros Menara site in Chad. Previous research had asserted that these bones were too ape-like to indicate upright walking; however, this latest study utilizes 3D shape modeling and anatomical analysis tailored to human locomotion.

“These characteristics suggest a similarity in hip and knee function between Sahelanthropus tchadensis and modern humans, possibly representing fundamental adaptations toward bipedalism in the human lineage,” the researchers concluded.

Although the external shape of the limb bones resembles that of chimpanzees, the proportions indicate a more human-like configuration.

The researchers found that the relationships between arm and leg lengths are comparable to modern bonobos and early human predecessors.

Notably, they discovered the femoral tubercle—a bony structure on the femur crucial for attaching the iliofemoral ligament, which stabilizes the human hip joint—unique to hominids.

Additionally, the femur exhibited significant internal torsion known as front twist (medial torsion of the femoral shaft), a feature linked to aligning the knee with the body’s center of gravity during walking, distinctly present in hominids compared to extant apes and extinct Miocene species.

These findings challenge long-held beliefs regarding the timeline and mechanics of upright walking evolution.

Scientists propose that bipedalism emerged gradually rather than as a sudden change. “We consider the evolution of bipedalism as an ongoing process,” researchers stated.

Sahelanthropus tchadensis could represent an early form of habitual bipedalism.”

“In addition to terrestrial bipedalism, Sahelanthropus tchadensis likely engaged in various arboreal activities, including vertical climbing, forelimb suspension from branches, and both arboreal quadrupedal and bipedal locomotion.”

The study interprets this fossil as evidence of early human evolution from an ape-like ancestor, asserting that chimpanzee-like species are positioned near the root of the human family tree.

“Our analysis reveals that Sahelanthropus tchadensis demonstrates an early adaptation for bipedalism, suggesting that this trait evolved early in our lineage from ancestors closely related to present-day chimpanzees and bonobos,” Dr. Williams stated.

For further details, refer to the study published in this month’s issue of Scientific Advances.

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Scott A. Williams et al., 2026. The Earliest Evidence of Bipedalism in Humans: Sahelanthropus tchadensis. Scientific Advances 12(1); doi: 10.1126/sciadv.adv0130

Source: www.sci.news

Remarkable Discovery: 160 Million-Year-Old Dinosaur Footprints Unearthed in Chile

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The recently uncovered theropod and sauropod footprints from the Late Jurassic Mahara Formation are the oldest dinosaur tracks documented in Chile and along the western edge of the ancient supercontinent Gondwana.

Palaeoartistic reconstruction of Quebrada Huatacon from the Late Jurassic period. Image credit: Nahuel Vazquez.

“The Late Jurassic fossil record highlights significant disparities in the density and distribution of dinosaur footprints between Laurasia and Gondwana,” stated Dr. Marco Yurac from the School of Paleontology and his colleagues.

“In Europe alone, numerous footprint sites have been identified, including regions in Italy, Croatia, Poland, Spain, Switzerland, France, Germany, and Portugal.”

“Moreover, North America boasts extensive track sites rich in ichthyological evidence.”

“Conversely, dinosaur footprints in Gondwana are relatively scarce and fragmentary, with notable exceptions like footprint-bearing outcrops in the High Atlas Mountains of Morocco.”

“Beyond these, ichthyological evidence is limited, with only a few records from Australia.”

“In South America, the majority of dinosaur footprints are found along the eastern coast, particularly in Brazil, Guyana, and Uruguay, with additional reports from northern locales like Colombia.”

“In contrast, on the western coast of South America, corresponding to Gondwana’s western boundary, Late Jurassic dinosaur footprints have only been discovered in Chile.”

A track consisting of four consecutive imprints from a large three-fingered dinosaur in the Mahalla Formation of Chile. Image credit: Yurac et al., doi: 10.1186/s13358-025-00419-9.

Paleontologists have discovered five distinct formations containing footprints within the Majara Formation in the Quebrada Huatacondo area of Chile.

These footprints were created by theropod and sauropod dinosaurs approximately 160 million years ago.

“Around 160 million years ago, northern Chile experienced cycles of flooding and drought,” explained the researchers.

“While the climate was primarily arid, temporary wetlands formed from seasonal water accumulation, attracting a variety of animals, from small theropods to massive carnivorous dinosaurs.”

“As dinosaurs traversed wet mud near these water sources, their footprints were imprinted into the soft sediment.”

“Subsequent flooding gently covered these tracks, preserving them for millions of years.”

The Majara footprints reveal the existence of giant (51-52.8 cm), large (43.5-46.5 cm), and medium-sized (25-27 cm) theropod dinosaurs.

One surface showcases over 25 footprints (ranging from 8 to 13 cm), attributed to microscopic theropods.

“These footprints represent the smallest theropod prints ever recorded in Chile, and likely extend across the entire western margin of Gondwana,” said the scientists.

Another surface is the only stratigraphic level exhibiting solely sauropod footprints (potentially undertracks).

“Due to their poor state of preservation, exact quantitative measurements were not feasible,” commented the authors.

“Nonetheless, analyses of the digital model suggest at least nine footprints with configurations indicative of potential movements.”

Paleontologists assert that this discovery represents the earliest known dinosaur footprints from Chile and the western margin of Gondwana.

“These footprints offer crucial insights for reconstructing the paleoenvironment and behavioral patterns of dinosaurs in northern Chile during the Late Jurassic, reflecting the temporary inhabitation of semi-arid floodplain and ephemeral wetland ecosystems,” the researchers concluded.

This significant finding is detailed in a research paper published in the Swiss Journal of Paleontology.

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M. Yurac et al. 2025. Upper Jurassic dinosaur footprints from the Mahara Formation of the Huatacondo region (Tarapaca Basin, Chile): Reassessment of known localities and discovery of new footprints. Swiss Journal of Paleontology 144, 72; doi: 10.1186/s13358-025-00419-9

Source: www.sci.news

Archaeologists Unearth 2.75 Million-Year-Old Stone Tools in Kenya

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Archaeologists have unearthed Oldowan stone tools across three distinct archaeological layers at the Namorotuknan site, dated to roughly 300,000 years (2.75 million to 2.44 million years ago) within the Koobifora Formation in northeastern Turkana Basin, Marsabit District, Kenya. This discovery, indicating careful selection of rock materials, points to the sustained practice of toolmaking across epochs.

A 2.58 million year old stone tool excavated from the Namorotuknan ruins in Kenya. Image credit: Brown others., doi: 10.1038/s41467-025-64244-x.

The initial phases of toolmaking, which date back over 3 million years, emphasize percussion techniques that are prevalent in the human lineage and shared with other primates.

The practice of tool use associated with extractive foraging continues to be a notable aspect of certain modern primate species.

The earliest structured creation of sharp stone tools, referred to as Oldowan, has been documented at hominin sites in eastern Africa: Lady Gerar and Gona in the Afar Basin (2.6 million years ago), Ethiopia, and Nyayanga in western Kenya (2.6 to 2.9 million years ago).

Professor David R. Brown, an anthropologist at George Washington University and the Max Planck Institute for Evolutionary Anthropology, along with his team, discovered stone tools across three archaeological horizons at the Namorotuknan site, estimated to be 2.75 million years ago, 2.58 million years ago, and 2.44 million years ago.

“This site tells an extraordinary story of cultural continuity,” Professor Brown remarked.

“What we observe is a long-standing tradition of technology rather than a singular innovation.”

“Our findings imply that tool usage might have been a more widespread adaptation among our primate ancestors,” stated Dr. Susana Carvalho, science director at Gorongosa National Park in Mozambique.

“Namorotsukunan offers a unique perspective into a transforming world: flowing rivers, fierce fires, expanding arid regions, and resilient tools.”

Stone tools discovered at the Three Horizons site at the Namorotuknan site in Kenya. Image credit: Brown others., doi: 10.1038/s41467-025-64244-x.

“For 300,000 years, the same tools have endured, possibly revealing the origins of our fundamental habit of using technology to adapt to change,” remarked Dr. Dan V. Parc Laurier, a researcher at GeoEcoMar, Utrecht University, and the University of São Paulo.

“Early humans showed remarkable consistency in creating sharp stone tools, reflecting advanced technology and knowledge handed down through numerous generations.”

Researchers have utilized volcanic ash dating, ancient sediment magnetic signals, chemical signatures in rocks, and microscopic plant remains to construct a broad narrative of climate change, providing context for the influence of technology on human evolution.

These toolmakers managed to persevere through significant environmental transformations. Their innovative technology facilitated new dietary practices, including the consumption of meat, transforming challenges into survival advantages.

“These discoveries indicate that humans had already mastered the creation of sharp stone tools by approximately 2.75 million years ago, suggesting that the inception of Oldowan technology is older than previously believed,” stated Dr. Nigas Baraki, a researcher at George Washington University.

Dr. Francis Forrest, a researcher at Fairfield University, added: “At Namorotuknan, cut marks connect stone tools with carnivory, indicating a diverse diet that thrived amidst shifting landscapes.”

“The record of plant fossils narrates a fascinating tale: the landscape transitioned from rich wetlands to fire-prone arid grasslands and semi-deserts,” noted Dr. Rahab N. Kinyanjui, a researcher at the National Museum of Kenya and the Max Planck Institute for Geoanthropology.

“Despite changes in vegetation, the production of tools remained consistent. This reflects resilience.”

of result Posted in today’s diary nature communications.

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Dr. Brown others. 2025. Early Oldowan technology flourished during Pliocene environmental change in the Turkana Basin of Kenya. Nat Commun 16, 9401;doi: 10.1038/s41467-025-64244-x

Source: www.sci.news

Ancient Training Species Discovered: A 75 Million-Year-Old Find | Sci.News

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The newly identified dragonfly species, Corduladensa asorni, found in Alberta’s Dinosaur Regional Park, represents Canada’s sole Mesozoic dragonfly, bridging a significant 30 million-year gap in the evolutionary lineage of dragonflies.

Corduladensa asorni. Image credit: Alex Anderson.

The fossilized wings of Corduladensa asorni were uncovered in 2023 by undergraduate students at McGill University during a vertebrate paleontology field course at Dinosaur State Park.

“We were digging in areas where numerous leaf fossils had been found, breaking the rocks,” explained Andre Mueller, a paleontologist from McGill University.

“When we uncovered the partial wings, we were astonished, as we didn’t anticipate discovering insects in that location.”

Due to its remarkable characteristics and unique anatomy, Corduladensa asorni led researchers to establish a new family called Cordualadensidae.

“This marks the first dragonfly from the age of dinosaurs identified in Canada,” noted Mueller.

“Its wingspan was comparable to that of a human hand, and although it was small, it played a crucial role in the Cretaceous ecosystem.”

Fossil wings of Corduladensa asorni. Image credits: Mueller et al., doi: 10.1139/cjes-2024-0162.

“This discovery showcases impression fossils, an entirely new method of preserving local insect fossils, effectively doubling our knowledge of insects from the Dinosaur Regional Parks,” stated Dr. Alexandre Demars Potvin from McGill University.

“We have begun to find more insect fossils by broadening our search areas and methodologies.”

“The diversity of insect life during this era would have been far greater than previously believed.”

The discovery of Corduladensa asorni aids in closing a 30 million-year evolutionary gap.

It is also the first known member of a significant group of dragonflies termed Cavilabiata found in North America.

“The wing anatomy indicates that this species was adapted for gliding, a trait associated with today’s migratory dragonflies and likely vital to their success,” commented Professor Hans Larson of McGill University.

“This specimen offers insight into what life in Canada was like 75 million years ago and provides an important new piece of the ecological puzzle in one of the most diverse regions rich in dinosaur fossils.”

The team’s publication was released this month in the Canada Journal of Earth Science.

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Andre S. Mueller et al. A new family of fossil dragonfly (Odonata, Kabilaviata) from the Late Cretaceous (Campanian) Dinosaur Park Formation in Alberta, Canada. Canada Journal of Earth Science Published online on August 1, 2025. doi:10.1139/cjes-2024-0162

Source: www.sci.news

New Molar Species Identified from 3.2 Million-Year-Old Fossils

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Paleontologists have discovered a new genus and species within the Talpidae family, based on a partial skeleton found at a Pliocene Age site in Camp dels Ninotto, Girona, Spain.

Reconstructing the life of Vulcanoscaptor ninoti. Image credit: Jesus Gamara / Ifesquelka.

The newly identified species is named Vulcanoscaptor ninoti. This mole lived in Spain approximately 3.25 million years ago.

The fossilized skeleton was uncovered in 2010 at the Camp del Sninott site in Girona, Spain.

“This specimen includes the mandible with complete dentition, parts of the trunk, and some bones from both fore and hind limbs, many of which are still in anatomical relationships.”

“Exceptional preservation is exceedingly rare in small mammals like moles, making this specimen one of the oldest and most complete in Europe.”

“These fossils represent the most comprehensive mole fossils known from the Pliocene in Europe, offering significant insights into the evolutionary history of talpid.”

The fossils were partially encased in dense sediment blocks and were fully extracted during excavation.

To study it without causing damage, paleontologists utilized high-resolution microcomputed tomography (MicroCT) scans, allowing for precise 3D digital reconstruction of the skeletons.

“MicroCT enabled us to analyze very small and delicate structures such as phalanges and teeth.”

“This technological approach allowed us to identify unique anatomical features and incorporate them into a robust phylogenetic analysis.”

The structure of Vulcanoscaptor ninoti shows that both the forelimbs and hind limbs exhibit a high degree of adaptation to an underground lifestyle.

“The humerus is particularly robust, featuring a wide array of prominent muscle attachment sites, suggesting strong digging capabilities,” said Dr. Linares.

“However, the preservation of this specimen in lake sediments and its lateral position increases the likelihood that it possessed some aquatic mobility.”

“While we can’t confirm this definitively, there’s a modern mole that excels at both digging and swimming.”

According to the team, Vulcanoscaptor ninoti was part of the Scaropini tribe, which includes moles found today in parts of North America and Asia.

This finding from the Pliocene of Europe indicates a more complicated evolutionary and paleogeographic scenario than previously believed.

“Our explanation of Vulcanoscaptor ninoti confirms that the evolutionary history of moles is far more dynamic than previously understood, suggesting possible intercontinental dispersion and a greater anatomical diversity than previously acknowledged,” said one of the authors.

“It also emphasizes the significance of exceptional fossil sites in preserving species that are rarely found in the fossil record, like small mammals.”

“Despite its distinct fossil morphology, this mole shares close ties with present-day North American species from the genera Scapanus and Scaropas, indicating a more intricate evolutionary history than we previously assumed,” added Dr. Juliolio.

“Its presence in Europe points to past transcontinental migration of moles, challenging the notion that they are low-dispersive mammals.”

The team’s paper was published this month in the journal Scientific Reports.

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A. Linares-Martín et al. 2025. Unexpected scalopinimols (mammals) from the Pliocene of Europe shed light on thalpido phylogeny. Sci Rep 15, 24928; doi:10.1038/s41598-025-10396-1

Source: www.sci.news