Some fish can recognize their own faces in photos and mirrors, an ability usually attributed to humans and other animals considered particularly brainy, such as chimpanzees, scientists report. Finding the ability in fish suggests that self-awareness may be far more widespread among animals than scientists once thought.
“It is believed widely that the animals that have larger brains will be more intelligent than animals of the small brain,” such as fish, says animal sociologist Masanori Kohda of Osaka Metropolitan University in Japan. It may be time to rethink that assumption, Kohda says.
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Kohda’s previous research showed that bluestreak cleaner wrasses can pass the mirror test, a controversial cognitive assessment that purportedly reveals self-awareness, or the ability to be the object of one’s own thoughts. The test involves exposing an animal to a mirror and then surreptitiously putting a mark on the animal’s face or body to see if they will notice it on their reflection and try to touch it on their body. Previously only a handful of large-brained species, including chimpanzees and other great apes, dolphins, elephants and magpies, have passed the test.
In a new study, cleaner fish that passed the mirror test were then able to distinguish their own faces from those of other cleaner fish in still photographs. This suggests that the fish identify themselves the same way humans are thought to — by forming a mental image of one’s face, Kohda and colleagues report February 6 in the Proceedings of the National Academy of Sciences .
“I think it’s truly remarkable that they can do this,” says primatologist Frans de Waal of Emory University in Atlanta who was not involved in the research. “I think it’s an incredible study.”
De Waal is quick to point out that failing the mirror test should not be considered evidence of a lack of self-awareness. Still, scientists have struggled to understand why some species that are known to have complex cognitive abilities, such as monkeys and ravens, have not passed. Researchers have also questioned whether the test is appropriate for species like dogs that rely more on scent, or like pigs that may not care enough about a mark on their bodies to try to touch it.
The mixed results in other animals make it all the more astonishing that a small fish can pass. In their first mirror test studies, published in 2019 and 2022 , Kohda’s team exposed wild-caught cleaner fish in separate tanks to mirrors for a week. The researchers then injected brown dye just beneath the scales on the fish’s throats, making a mark that resembles the parasites these fish eat off the skin of larger fish in the wild. When the marked fish saw themselves in a mirror, they began striking their throats on rocks or sand in the bottom of the tank, apparently trying to scrape off the marks.
In the new study, 10 fish that passed the mirror test were then shown a photo of their own face and a photo of an unfamiliar cleaner fish face. All the fish acted aggressively toward the unfamiliar photo, as if it were a stranger, but were not aggressive toward the photo of their own face.
When another eight fish that had spent a week with a mirror but had not previously been marked were shown a photo of their own face with a brown mark on the throat, six of them began scraping their throats just like the fish that passed the mirror test. But they did not scrape when shown a photo of another fish with a mark.
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Animals that recognize their reflection in the mirror most likely first learn to identify themselves by seeing that the movement of the animal in the mirror matches their own movement, researchers think. Because the cleaner fish were also able to recognize their own faces in still images, they, and possibly other animals that have passed the mirror test, may be able to identify themselves by developing a mental image of their own face that they can compare to what they see in the mirror or photos, the authors say.
“I think it’s a great next step,” says comparative cognitive psychologist Jennifer Vonk of Oakland University in Rochester, Mich., who wasn’t involved in the study. But she would like to see more research before drawing conclusions about what’s being represented in the mind of a nonverbal being like a fish. “As with most other studies, it still leaves some room for further follow-up.”
Kohda’s lab has more experiments planned to continue to probe what’s going on in the brain of the cleaner fish, and to try the new photo-recognition method on another popular research fish, the three-spined stickleback ( Gasterosteus aculeatus ).
Animal behaviorist Jonathan Balcombe, author of the book What a Fish Knows , is already convinced, describing the new study as “robust and quite brilliant.” People shouldn’t be surprised that fish could be self-aware given that they have already been shown to have complex behavior including tool use, planning and collaboration, Balcombe says. “It’s time we stopped thinking of fishes as somehow lesser members of the vertebrate pantheon.”
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A powerful magnitude 7.8 earthquake struck southern Turkey, including the province of Hatay (shown) on February 6, setting off a desperate race for survivors.
In the early morning of February 6, a devastating magnitude 7.8 earthquake struck southern Turkey, near the border with Syria. Numerous aftershocks followed, the strongest nearly rivaling the power of the main quake, at magnitude 7.5. By evening, the death toll had climbed to more than 3,700 across both countries, according to Reuters, and was expected to continue to rise.
Most of Turkey sits on a small tectonic plate that is sandwiched between two slowly colliding behemoths: the vast Eurasian Plate to the north and the Arabian Plate to the south. As those two plates push together, Turkey is being squeezed out sideways, like a watermelon seed snapped between two fingers, says seismologist Susan Hough of the U.S. Geological Survey.
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The entire country is hemmed in by strike-slip, or sideways-sliding, fault zones: the North Anatolian Fault that runs roughly parallel to the Black Sea, and the East Anatolian Fault, near the border with Syria. As a result, Turkey is highly seismically active. Even so, Monday’s quake, which occurred on the East Anatolian Fault, was the strongest to strike the region since 1939, when a magnitude 7.8 quake killed 30,000 people.
Science News talked with Hough, who is based in Pasadena, Calif., about the quake, its aftershocks and building codes. The conversation has been edited for length and clarity.
SN : You say on Twitter that this was a powerful quake for a strike-slip fault. Can you explain?
Hough : The world has seen bigger earthquakes. Subduction zones generate the biggest earthquakes , as much as magnitude 9 ( SN: 1/13/21 ). But quakes close to magnitude 8 are not common on strike-slip faults. But because they’re on land and tend to be shallow, you can get severe … shaking close to the fault that’s moving.
SN : Some of the aftershocks were very strong, at magnitudes 7.5 and 6.7. Is that unusual?
Hough : As with a lot of things, there’s what’s expected on average, and there’s what’s possible. On average, the largest aftershocks are a full unit smaller than the main shock. But that’s just average; for any individual main shock, the largest aftershock can have a lot of variability.
The other thing people noted was the distance [between the main shock and some aftershocks over a hundred kilometers away]. Aftershock as a term isn’t precise. What is an aftershock isn’t something that seismologists are always clear on. The fault that produced the main shock is 200 kilometers long, and that’s going to change the stress in a lot of areas. Mostly it releases stress, but it does increase stress in some areas. So you can get aftershocks along that fault, but also some distance away. It’s a little bit unusual, but not unheard of.
SN : People have wondered whether Monday’s magnitude 3 earthquake near Buffalo, N.Y., might be related.
Hough : A magnitude 7.8 quake generates [seismic] waves that you can record all around Earth, so it’s technically disrupting every point on Earth. So it’s not a completely outlandish idea, but it’s statistically exceedingly unlikely. Maybe if a seismic wave passed through a fault that was just ready to go in just the right way, it’s possible.
An interesting [and completely separate] idea is that you might get earthquakes around the perimeter of the Great Lakes [such as near Buffalo] because as the lake levels go up and down, you’re stressing the Earth’s crust, putting weight on one side or the other. That’s a source of stress that could give you these pretty small quakes.
SN : The images emerging from this deadly disaster are devastating.
Hough : It’s hard to watch. And it hammers home the importance of building codes. One of the problems that any place is up against is that building codes improve over time, and you’ve always got the problem of older structures. It’s really expensive to retrofit. I expect that earthquake engineers will be looking at the damage, and it will illuminate where the vulnerabilities are [in the area]. The hope is that with proper engineering, we can make the built environment safe.
Carolyn Gramling is the earth & climate writer. She has bachelor’s degrees in geology and European history and a Ph.D. in marine geochemistry from MIT and the Woods Hole Oceanographic Institution.
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For mammals, one secret to a long life may be spending it living with friends and family.
An analysis of the life spans and social lives of nearly 1,000 mammal species shows that species that live in groups, such as horses and chimpanzees, tend to live longer than solitary beasts, like weasels and hedgehogs. The finding suggests that life span and social traits are evolutionarily entwined in mammals, researchers report January 31 in Nature Communications .
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The maximum life span of mammals ranges widely. The shortest-lived shrews, for example, survive about two years, while bowhead whales ( Balaena mysticetus ) can reach roughly 200 years of age ( SN : 1/6/15 ).
When evolutionary biologist Xuming Zhou of the Chinese Academy of Sciences in Beijing was studying the longest-lived mammals to understand the evolution of longevity, he took particular note of naked mole-rats ( Heterocephalus glaber ). The rodents are exceptionally long-lived, sometimes reaching over 30 years of age. They also live in huge, complex, subterranean societies. In contrast, other rodents like golden hamsters ( Mesocricetus auratus ), which are solitary, live to only about four years.
Some previous research on specific mammal species showed an effect of social behavior on longevity, Zhou says. For instance, female chacma baboons ( Papio ursinus ) with strong, stable social bonds live longer than females without them.
Zhou and his colleagues decided to see if there were any links between longevity and social habits shared across a wide range of mammal species.
The researchers compiled information from the scientific literature on the social organization of 974 mammal species. They then split these species into three categories: solitary, pair-living and group-living. When the researchers compared these three groups with data on the mammals’ known longevity, they found that group-living mammals tended to live longer than the solitary species — roughly 22 years compared with nearly 12 years in solitary mammals.
Zhou and his colleagues then accounted for body mass — bigger mammals tend to live longer than smaller ones — and the effect of social bonds held. A stark example comes from shrews and bats. Both are similarly tiny mammals, but the loner shrews live only a few years, while some far more social bat species can live for 30 or 40 years.
“We were so surprised, because individuals who live in groups also face a lot of costs, such as competition for potential mating partners and food,” Zhou says. Frequent social contact in group settings can also encourage the spread of infectious disease.
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But there are benefits to living in a group too, he says, such as banding together for protection against predators. Living together may also reduce the risk of starvation if, for instance, group members increase foraging efficiency by finding and gathering food together. These factors may allow social mammals to live longer.
The evolution of a long life may also be more likely in group-living species: Living in a group allows animals to potentially aid the survival of their family members, which carry their genes.
Evolutionary biologist Laurent Keller of the University of Lausanne in Switzerland lauds the study for the sheer size of the sampling effort. “But it would have been useful to be a bit more precise about different levels of sociality.” There are more variations of social organization within the three categories used in the study, he says, and the relative degree of sociality could influence any patterns you see.
Still, fine tuning the social categories “is not an easy task,” Keller notes.
To get an idea of how genes might produce the link between longevity and group living, Zhou and his team took brain tissue samples from 94 mammal species and analyzed the transcriptome — the full complement of RNA — giving insights into different genes’ activity levels. This can reveal whether genes are turned on or off, or how much protein the genes may be instructing cells to produce.
The researchers found 31 genes whose relative activity levels were correlated with both longevity and one of the three prescribed social categories. Many of these genes appear to have roles in the immune system, which may have importance when countering pathogens spreading through the social group. Other genes were associated with hormone regulation, including some thought to influence social behaviors.
In studying these genes in more detail, Zhou envisions uncovering more about how mammals’ social habits and life spans have evolved together.
Jake Buehler is a freelance science writer, covering natural history, wildlife conservation and Earth’s splendid biodiversity, from salamanders to sequoias. He has a master’s degree in zoology from the University of Hawaii at Manoa.
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Particles of twisted light that have been entangled using quantum mechanics offer a new approach to dense and secure data storage.
Holograms that produce 3-D images and serve as security features on credit cards are usually made with patterns laid down with beams of laser light. In recent years, physicists have found ways to create holograms with entangled photons instead. Now there is, literally, a new twist to the technology.
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Light can move in a variety of ways, including the up-and-down and side-to-side patterns of polarized light. But when it carries a type of rotation known as orbital angular momentum, it can also propagate in spirals that resemble twisted rotini pasta.
Like any other photons, the twisted versions can be entangled so that they essentially act as one entity. Something that affects one of an entangled photon pair instantly affects the other, even if they are very far apart.
In previous experiments, researchers have sent data through the air in entangled pairs of twisted photons ( SN: 8/5/15 ). The approach should allow high-speed data transmission because light can come with different amounts of twist, with each twist serving as a different channel of communication.
Now the same approach has been applied to record data in holograms. Instead of transmitting information on multiple, twisted light channels, photon pairs with different amounts of twist create distinct sets of data in a single hologram. The more orbital angular momentum states involved, each with different amounts of twist, the more data researchers can pack into a hologram.
In addition to cramming more data into holograms, increasing the variety of twists used to record the data boosts security. Anyone who wants to read the information out needs to know, or guess, how the light that recorded it was twisted.
For a hologram relying on two types of twist, says physicist Xiangdong Zhang of the Beijing Institute of Technology, you would have to pick the right combination of the twists from about 80 possibilities to decode the data. Bumping that up to combinations of seven distinct twists leads to millions of possibilities. That, Zhang says, “should be enough to ensure our quantum holographic encryption system has enough security level.”
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The researchers demonstrated their technique by encoding words and letters in holograms and reading the data back out again with twisted light. Although the researchers produced images from the holographic data, says physicist Hugo Defienne of the Paris Institute of Nanosciences, the storage itself should not be confused with holographic images.
Defienne, who was not involved with the new research, says that other quantum holography schemes, such as his efforts with polarized photons, produce direct images of objects including microscopic structures.
“[Their] idea there is very different . . . from our approach in this sense,” Defrienne says. “They’re using holography to store information,” rather than creating the familiar 3-D images that most people associate with holograms.
The twisted light data storage that Zhang and his colleagues demonstrated is slow, requiring nearly 20 minutes to decode an image of the acronym “BIT,” for the Beijing Institute of Technology where the experiments were performed. And the security that the researchers have demonstrated is still relatively low because they included only up to six forms of twisted light in their experiments.
Zhang is confident that both limitations can be overcome with technical improvements. “We think that our technology has potential application in quantum information encryption,” he says, “especially quantum image encryption.”
James Riordon is a freelance science writer who covers physics, math, astronomy and occasional lifestyle stories.
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Dugongs, like this juvenile in the Red Sea off the coast of Egypt, were recently added to the IUCN Red List of Threatened Species. Under a new metric that accounts for cultural connections between species and humans, dugongs are endangered.
In shallow coastal waters of the Indian and Pacific oceans, a seagrass-scrounging cousin of the manatee is in trouble. Environmental strains like pollution and habitat loss pose a major threat to dugong ( Dugong dugon ) survival, so much so that in December, the International Union for Conservation of Nature upgraded the species’ extinction risk status to vulnerable. Some populations are now classified as endangered or critically endangered.
If that weren’t bad enough, the sea cows are at risk of losing the protection of a group who has long looked after them: the Torres Strait Islanders. These Indigenous people off the coast of Australia historically have been stewards of the dugong populations there, sustainably hunting the animals and monitoring their numbers. But the Torres Strait Islanders are also threatened, in part because sea levels are rising and encroaching on their communities, and warmer air and sea temperatures are making it difficult for people to live in the region.
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The findings clearly illustrate that biology shouldn’t be the primary factor in shaping conservation policy, says cultural anthropologist Victoria Reyes-García. When a culture dwindles, the species that are important to that culture are also under threat. To be effective, more conservation efforts need to consider the vulnerability of both the species and the people that have historically cared for them, she says.
“ A lot of the people in the conservation arena think we need to separate people from nature,” says Reyes-García, of the Catalan Institution for Research and Advanced Studies and the Autonomous University of Barcelona. But that tactic overlooks the caring relationship many cultural groups – like the Torres Strait Islanders – have with nature, she says.
“Indigenous people, local communities, also other ethnic groups – they are good stewards of their biodiversity,” says Ina Vandebroek, an ethnobotanist at the University of the West Indies at Mona in Kingston, Jamaica, who was not involved in the work. “They have knowledge, deep knowledge, about their environments that we really cannot overlook.”
One way to help shift conservation efforts is to give species a “biocultural status,” which would provide a fuller picture of their vulnerability, Reyes-García and colleagues say. In the study, the team used existing language vitality research to determine a culture’s risk of disappearing: The more a cultural group’s language use declines, the more that culture is threatened. And the more a culture is threatened, the more culturally vulnerable its important species are. Researchers then combined a species’ cultural and biological vulnerability to arrive at its biocultural status. In the dugong’s case, its biocultural status is endangered, meaning it is more at risk than its IUCN categorization suggests.
This intersectional approach to conservation can help species by involving the people that have historically cared for them ( SN: 3/2/22 ). It can also highlight when communities need support to continue their stewardship, Reyes-García says. She hopes this new framework will spark more conservation efforts that recognize local communities’ rights and encourage their participation – leaning into humans’ connection with nature instead of creating more separation ( SN: 3/8/22 ).
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Muon scans are helping to find flaws and archeological surprises inside an ancient fortress wall in the Chinese city of Xi’an, which has grown and modernized since the wall was built nearly 650 years ago.
For nearly 650 years, the fortress walls in the Chinese city of Xi’an have served as a formidable barrier around the central city. At 12 meters high and up to 18 meters thick, they are impervious to almost everything — except subatomic particles called muons.
Now, thanks to their penetrating abilities, muons may be key to ensuring that the walls that once protected the treasures of the first Ming Dynasty — and are now a national architectural treasure in their own right — stand for centuries more.
A refined detection method has provided the highest-resolution muon scans yet produced of any archaeological structure, researchers report in the Jan. 7 Journal of Applied Physics . The scans revealed interior density fluctuations as small as a meter across inside one section of the Xi’an ramparts. The fluctuations could be signs of dangerous flaws or “hidden structures archaeologically interesting for discovery and investigation,” says nuclear physicist Zhiyi Liu of Lanzhou University in China.
Muons are like electrons, only heavier. They rain down all over the planet, produced when charged particles called cosmic rays hit the atmosphere. Although muons can travel deep into earth and stone, they are scattered or absorbed depending on the material they encounter. Counting the ones that pass through makes them useful for studying volcano interiors, scanning pyramids for hidden chambers and even searching for contraband stashed in containers impervious to X-rays ( SN: 4/22/22 ).
Though muons stream down continuously, their numbers are small enough that the researchers had to deploy six detectors for a week at a time to collect enough data for 3-D scans of the rampart.
It’s now up to conservationists to determine how to address any density fluctuations that might indicate dangerous flaws, or historical surprises, inside the Xi’an walls.
James Riordon is a freelance science writer who covers physics, math, astronomy and occasional lifestyle stories.
Our mission is to provide accurate, engaging news of science to the public. That mission has never been more important than it is today.
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Your support enables us to keep our content free and accessible to the next generation of scientists and engineers. Invest in quality science journalism by donating today.
Science News was founded in 1921 as an independent, nonprofit source of accurate information on the latest news of science, medicine and technology. Today, our mission remains the same: to empower people to evaluate the news and the world around them. It is published by the Society for Science, a nonprofit 501(c)(3) membership organization dedicated to public engagement in scientific research and education (EIN 53-0196483).
