Ralph Holloway, Anthropologist Who Studied Brain's Evolution, Dies at 90
Ralph Holloway, an anthropologist who pioneered the idea that changes in brain structure, and not just size, were critical in the evolution of humans, died on March 12 at his home in Manhattan. He was 90.
His death was announced by Columbia University's anthropology department, where he taught for nearly 50 years.
Mr. Holloway's contrarian idea was that it wasn't necessarily the big brains of humans that distinguished them from apes or primitive ancestors. Rather, it was the way human brains were organized.
Brains from several million years ago don't exist. But Dr. Holloway's singular focus on casts of the interiors of skull fossils, which he usually made out of latex, allowed him to override this hurdle.
He 'compulsively collected' information from these casts, he wrote in a 2008 paper. Crucially, they offered a representation of the brain's exterior edges, which allowed scientists to get a sense of the brain's structure.
Using a so-called endocast, Dr. Holloway was able to establish conclusively, for instance, that a famous and controversial two-million-year-old hominid fossil skull from a South Africa limestone quarry, known as the Taung child, belonged to one of mankind's distant ancestors.
The Taung child's brain was small, leading many to doubt the conclusion of Raymond Dart, the anatomist who discovered it in the 1920s, that it was a human ancestor.
In 1969, Dr. Holloway took his family to South Africa to meet the elderly Dr. Dart, to examine the natural limestone endocast that the Taung child's positioning in the quarry had created and to make an endocast of his own.
'I became convinced that the Taung endocast needed independent study,' he wrote in 2008, in order to 'find an objective method(s) for deciding whether the cortex was reorganized as Dart had previously claimed,' so many years before.
Dr. Holloway focused on a crescent-shaped furrow, called the lunate sulcus, at the back of the endocast. In his view, it was positioned like a human's, which suggested to him that Dr. Dart had been right all along.
Others in the field had insisted that the Taung lunate sulcus was in a 'typical ape anterior position,' he wrote.
By now, the conclusions made by Dr. Holloway and Dr. Dart about the lunate sulcus have largely been accepted: The Taung child is a human ancestor.
'If you can define where it is and prove it, then you can really demonstrate that it is an aspect of reorganization,' Dr. Holloway told an interviewer for Archaeology magazine in 2007.
That concept — the brain's structure rather than its volume — was the decisive factor in proving human ancestry.
'I was taking the position, as had Dart before me, that reorganization took place prior to the increase in brain volume,' Dr. Holloway wrote in 2008.
'I believed then and remain convinced today that the earliest hominids, i.e., Australopithecus africanus, A. afarensis, and A. garhi, had brains that were definitely different from any ape's, despite their small size,' he added.
Early in his career, he had decided, unlike many of his peers, that the mere study of apes wasn't enough. 'I could not fathom using baboons as a theoretical model for understanding human evolution because I regarded each species as a terminal end product of their own line of evolutionary development,' he wrote.
It was humans, and the fossils of their ancestors, that needed to be the focus. 'He was very important in paleoanthropology, in bringing the study of brain evolution from being a marginal enterprise to the center,' said Chet C. Sherwood, a biological anthropologist at the George Washington University, in an interview.
'And he did it by innovating methods for reconstructing cranial morphology,' said Dr. Sherwood, who studied under Dr. Holloway at Columbia in the 1990s.
The confrontation between Dr. Holloway and his 'reorganization' partisans, on the one hand, and neuroanthopologists who insisted that Taung and similar specimens were more likely apes, on the other, could become 'extremely emotionally charged,' Dr. Holloway wrote. Of one such encounter, he wrote that 'fortunately, at 430 ml, the endocasts could not do much damage even if thrown, despite being made of plaster.'
Dr. Holloway was in some respects a traditional anthropologist, committed to what the discipline once called the 'four fields' of anthropology: archaeology and cultural, biological and linguistic anthropology. But that multidisciplinary approach has long fallen out of favor, with biologists increasingly pushed aside.
'I was quickly isolated and marginalized at Columbia, and remain so,' he wrote in 2008.
He was further isolated when he defended the educational psychologist Arthur R. Jensen, remembered for a deeply contested 1969 Harvard Educational Review article positing a genetic explanation for a divergence in I.Q. scores between Black and white people. One fellow anthropologist called him a 'racist,' Dr. Holloway wrote, after 'I had the temerity to defend Arthur Jensen' from an 'assertion that Jensen was a bigot.' Some who knew him said the charge was deeply unfair.
Ralph Leslie Holloway Jr. was born on Feb. 6, 1935, in Philadelphia, to Ralph Holloway, who was in the insurance business, and Marguerite (Grugan) Holloway, a secretary. He attended high school in Philadelphia and enrolled in Drexel Institute of Technology's metallurgical engineering program.
He later moved with his family to Albuquerque, where he studied anthropology and geology at the University of New Mexico, graduating in 1959 with a degree in geology.
After working for a time in the oil fields of southwest Texas and for Lockheed Aircraft in Burbank, Calif., he entered the graduate program in anthropology at the University of California, Berkeley, where he received his Ph.D. in 1964. That year, he was recruited by Columbia as an assistant professor, and he remained there until his retirement in 2003.
He was the author of or contributed to several books, including 'The Role of Human Social Behavior in the Evolution of the Brain' (1975).
Dr. Holloway is survived by his daughter, Marguerite Holloway, and two grandchildren. Two sons, Eric and Benjamin, and his first and second wives, Louise Holloway and Daisy Dwyer, are deceased.
For his entire career, Dr. Holloway remained focused on a single organ, the brain, and on the three-dimensional modeling he perfected to study its development.
'Because the human brain is the most important constructor of experience and reality, it would be important to know how it came to its present state,' he explained at the end of his career.
'Endocasts, i.e., the casts made of the internal table of bone of the cranium, are rather impoverished objects,' he continued, 'to achieve such an understanding, but these are all we have of the direct evolutionary history of our brains and should not be ignored.'
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
3 days ago
- Yahoo
The Ancient Star That Could Explain Where Gold Comes From
Tucked away in a stellar graveyard known as the Gaia Sausage, scientists have discovered a cosmic oddity with a potentially huge impact: a rare actinide-boost star called LAMOST J0804+5740. While the name may not be catchy, what's inside it could help explain one of the biggest lingering questions in modern astrophysics—how the universe formed its heaviest elements, including gold, uranium, and thorium. This star's unique chemical signature points to a history forged in some of the most violent conditions the cosmos has ever seen. According to researchers revealed that LAMOST J0804+5740 contains unusually high amounts of radioactive actinides, which are typically only produced in extreme events like neutron star collisions or exotic supernovae. That process, called the r-process (short for rapid neutron capture), is responsible for creating roughly half the elements heavier than iron. But there's a mystery: the few known cosmic events capable of fueling it are far too rare to explain the sheer volume of heavy elements found across the universe. That's where this weird star comes in. What makes J0804+5740 particularly interesting is its blend of high actinide levels and high metallicity, an unusual combo that defies expectations. Most actinide-rich stars are metal-poor and ancient. This one? It's old, but chemically rich, suggesting it may have originated in a now-merged dwarf galaxy outside the Milky Way. The leading theory? A violent, magneto-rotationally driven supernova—one of the most intense known cosmic explosions—could be the source. If confirmed, that would mark a major breakthrough in our understanding of the r-process and the birth of the elements that make up planets, people, and, yes, precious metals. "This means we don't yet have the complete picture," said Columbia University researcher Anirudh Patel. "Future observations […] will reveal more about the nature of r-process sites in the universe," Patel said. "Along with new and advanced theoretical models, this will be essential to resolving the r-process mystery and completing our understanding of the origin of the elements."The Ancient Star That Could Explain Where Gold Comes From first appeared on Men's Journal on Jun 5, 2025
Yahoo
3 days ago
- Yahoo
Where does the universe's gold come from? Giant flares from extreme magnetic stars offer a clue
When you buy through links on our articles, Future and its syndication partners may earn a commission. Scientists have finally gathered direct proof of how the universe forges its heaviest elements, a process that has remained a mystery for over half a century. A team from the Flatiron Institute in New York City calculated that giant flares emitted by magnetars — highly magnetic types of collapsed stars known as neutron stars — could be the long-sought cosmic forge that creates the universe's heavy elements. Just one of these giant flares could produce a planet's worth of gold, platinum, and uranium. "It's pretty incredible to think that some of the heavy elements all around us, like the precious metals in our phones and computers, are produced in these crazy extreme environments," Anirudh Patel, a doctoral candidate at Columbia University and lead author on a study of these elements, said in a statement. "Magnetar giant flares could be the solution to a problem we've had where there are more heavy elements seen in young galaxies than could be created from neutron star collisions alone." Lighter elements such as hydrogen, helium, and lithium were forged in the Big Bang, while heavier ones were formed through nuclear fusion in stellar cores during stars' lives — or in the aftermath of their explosive deaths. But just how neutron-rich elements that are heavier than iron are made has remained an open question. These elements are thought to form through a series of nuclear reactions known as the rapid neutron capture process, or r-process, which was long theorized to occur only under extreme conditions such as those in supernovas or neutron star mergers. In 2017, astronomers confirmed the r-process for the first time during the observed merger of two neutron stars. However, such collisions are so rare that they cannot fully account for the abundance of heavy elements in the universe and neutron star mergers happen too late in the universe's history to explain the earliest gold and other heavy elements. But the extreme neutron star flares that can forge these elements are much older. "The interesting thing about these giant flares is that they can occur really early in galactic history," Patel added. To study these processes, the NYC scientists turned to magnetars, whose magnetic fields are trillions of times stronger than Earth's. These stars occasionally produce "flares" — bursts of energy caused by the sudden release of magnetic energy, typically triggered by the rearrangement or decay of their magnetic fields. The team calculated that a magnetar's giant flare could create the right conditions for r-process elements to form, producing highly unstable radioactive nuclei that decay into stable heavy elements such as gold. Excitingly, the NYC team was able to link their calculations to a mysterious observation made in 2004 of a bright flash of light from the magnetar SGR 1806–20. Initially, the event didn't seem unusual — until researchers realized the flare's total energy was roughly a thousand times greater than that of typical bursts. "The event had kind of been forgotten over the years," said Brian Metzger, a senior research scientist at the CCA and a professor at Columbia University. "But we very quickly realized that our model was a perfect fit for it." "I wasn't thinking about anything else for the next week or two," Patel said in a NASA statement. "It was the only thing on my mind." By combining observations of SGR 1806–20's 2004 flare with their model, Metzger, Patel, and their colleagues estimated that the event likely produced around 2 million billion billion (you read that right) kilograms of heavy elements — roughly the mass of Mars or 27 moons! While such flares could account for about 10% of all heavy elements in our galaxy, the researchers note that the origins of the remaining 90% remain uncertain. "We can't exclude that there could be third or fourth sites out there that we just haven't seen yet," Metzger said. RELATED STORIES: — What happens inside neutron stars, the universe's densest known objects? — James Webb Space Telescope finds neutron star mergers forge gold in the cosmos: 'It was thrilling' — The most powerful explosions in the universe could reveal where gold comes from Eager to push their discovery further, the team plans to hunt for more magnetar flares using NASA's Compton Spectrometer and Imager mission, slated for launch in 2027 — a mission that could reveal even more secrets about the cosmic origins of gold and other heavy elements. "It's a pretty fundamental question in terms of the origin of complex matter in the universe," Patel said. "It's a fun puzzle that hasn't actually been solved." The team's research was published in The Astrophysical Journal Letters.
Yahoo
3 days ago
- Yahoo
How an odd star in the 'Gaia Sausage' could help solve one of astronomy's most enduring mysteries
When you buy through links on our articles, Future and its syndication partners may earn a commission. Astronomers have discovered an exceptionally rare star that may help to solve one of astronomy's enduring mysteries: where the universe's heaviest elements came from. The star, named LAMOST J0804+5740, resides in the Gaia Sausage (also called Gaia Enceladus), the ancient remnants of a dwarf galaxy that merged with the Milky Way roughly 8 billion to 11 billion years ago. This type of star, known as an actinide-boost star, has a high abundance of radioactive elements known as actinides. "The actinides are the heaviest group of elements on the periodic table," Anirudh Patel, a doctoral candidate in the Theoretical High Energy Astrophysics group at Columbia University who was not involved in the study, told "They include thorium and uranium, for example, and are produced by the r-process." The r-process, short for "rapid neutron capture process," is a series of nuclear reactions that occur in extreme astronomical environments, like during neutron star mergers or certain types of supernovas, where atomic nuclei rapidly absorb neutrons before they have a chance to decay, becoming heavier elements. "This is how approximately half of the elements in our universe heavier than iron are synthesized," Patel explained. "The r-process requires more extreme astrophysical environments than your typical nuclear fusion reactions that take place in the cores of massive stars. However, a complete understanding of the astrophysical origin of the r-process has remained elusive for decades." Direct observations of the r-process in action are rare. So far, astronomers have identified two likely cosmic sites where it occurs. One is the merger of neutron stars, and more recently, Patel and colleagues reported evidence that it may also occur within extremely magnetized neutron stars called magnetars. Although these discoveries are steps in the right direction, they still fall short of explaining how most of the universe's heavy elements came to be. Known r-process sites alone can't fully account for the observed abundance of heavy elements like uranium, thorium and gold. This is because they are too rare or infrequent to produce the sheer quantity of heavy elements we observe today, suggesting that other, yet-undiscovered sources must be contributing. Observations of J0804+5740, the first actinide-boost star identified in the Gaia Sausage, provide an exciting new piece of the puzzle. "The study reports a comprehensive set of chemical data, identifying a new r-process enriched star," Patel said. "This, along with other data and theoretical models, will play a role in [pinning down] the origin of the r-process elements in the universe." To determine which elements are present in a star and uncover the processes that produced them, astronomers use a technique known as atomic spectroscopy. "The idea is that electrons occupy different energy levels in atoms," Patel said. "The spacing between these energy levels can be different inside atoms of different elements. If an atom is sitting in the atmosphere of a star, it can absorb the light from the star, and its electrons can transition between the internal energy levels. Different elements have different atomic structure[s], so they will absorb different frequencies of light during these transitions." Using specialized instruments, scientists observe less light at specific colors where elements absorb it due to their internal energy levels. This helps them measure how much of those elements are in the star's atmosphere. The study's scientific team was excited that, after conducting an elemental analysis, they found that J0804+5740 represents a rare example of an actinide-boost star at relatively high metallicity — the overall abundance of elements heavier than helium in a star. Actinide-boost stars typically only show an unusually high number of actinides, like thorium and uranium, relative to other heavy elements produced by the r-process, but this boost usually appears in stars that are metal-poor or have low metallicity. This makes J0804+5740 a bit of an oddball. "Like most r-process enhanced stars, the abundance pattern of most heavy neutron-capture elements in J0804+5740 agrees well with the solar r-process, indicating that the main r-process produced these elements in the early universe," the team wrote in a paper published in The Astrophysical Journal Letters. "However, some elements exhibit deviations from [a typical] solar r-process abundance pattern." It follows the expected pattern for very heavy elements, but it also shows an unexpectedly high abundance of lighter r-process elements, like barium, lanthanum and cerium. "[Their abundance] in the star J0804+5740 is a few times larger than in our own solar system," Patel said. "This implies that there exist multiple types of r-process sites — in particular, one that could produce a relatively high abundance of these light r-process elements." To better understand the odd star's origins, the team analyzed the motions of J0804+5740 and similar stars. They found that actinide-boost stars are twice as likely to have come from outside the Milky Way, suggesting they were born in smaller galaxies that were later pulled into ours. This points to an important clue: The actinide-boost phenomenon may be more common in older, smaller galaxies. Theoretical models indicate that one possible source could be a rare and powerful explosion known as a magneto-rotationally driven supernova. These extreme events could create the kind of neutron-rich environments needed to produce actinides, particularly in galaxies like the Gaia Sausage. RELATED STORIES: —The most powerful explosions in the universe could reveal where gold comes from —Nearby asteroid may contain elements 'beyond the periodic table,' new study suggests —Where does the universe's gold come from? Giant flares from extreme magnetic stars offer a clue "The theoretical models are promising, but they are not without their uncertainties," Patel said. "More observational constraints are needed to assess how well these models reproduce what actually happens in nature." Regardless, these elemental deviations in J0804+5740 suggest a more complex nucleosynthetic origin — possibly involving multiple types of r-process events or contributions from other processes beyond the main r-process. "This means we don't yet have the complete picture," Patel said. "Future observations […] will reveal more about the nature of r-process sites in the universe," Patel said. "Along with new and advanced theoretical models, this will be essential to resolving the r-process mystery and completing our understanding of the origin of the elements."
