A cosmic 'CT scan' shows the universe is far more complex than expected
When you buy through links on our articles, Future and its syndication partners may earn a commission.
A powerful combination of data from two very different astronomical surveys has allowed researchers to build a "cosmic CT scan" of the universe's evolution.
These snapshots reveal that, as forces like gravity have reshaped the universe, the universe has in turn become less clumpy. In other words, the universe grew more complicated than expected. The team behind these findings used the sixth and final data release from the Atacama Cosmology Telescope (ACT) in combination with Year 1 data from the Dark Energy Spectroscopic Instrument (DESI) to reach these conclusions. This powerful combination of data allowed the researchers to layer cosmic time, akin to stacking ancient cosmic photographs over recent images of the universe, creating a multidimensional perspective of the cosmos.
"This process is like a cosmic CT scan, where we can look through different slices of cosmic history and track how matter clumped together at different epochs," team co-leader Mathew Madhavacheril of the University of Pennsylvania said in a statement. "It gives us a direct look into how the gravitational influence of matter changed over billions of years."
In order for the team to build this so-called CT scan of the universe, they needed to turn to light that has existed almost as long as the cosmos itself. With such ancient light, it's possible to track the changes the universe underwent as gravity reshaped it over around 13.8 billion years.
"ACT, covering approximately 23% of the sky, paints a picture of the universe's infancy by using a distant, faint light that's been traveling since the Big Bang," team co-leader paper Joshua Kim, a graduate researcher in the Madhavacheril Group, said in the statement. "Formally, this light is called the Cosmic Microwave Background (CMB), but we sometimes just call it the universe's baby picture because it's a snapshot of when it was around 380,000 years old."
The CMB is light left over from an event that happened shortly after the Big Bang called the "last scattering." This occurred when the universe had expanded and cooled enough to allow electrons and protons to form the first neutral atoms of hydrogen. The disappearance of free electrons meant that photons, aka particles of light, were free to travel without being endlessly scattered. In other words, the universe suddenly went from being opaque to being transparent. Today, that first light is seen as the CMB, also known as the "surface of last scattering."
Though often described as a "cosmic fossil," the CMB hasn't remained entirely unchanged for billions of years. The expansion of the universe has caused its photons to shift to longer wavelengths and lose energy. Its temperature is now uniform at minus 454 degrees Fahrenheit (minus 270 degrees Celsius).
Because mass warps the fabric of spacetime, giving rise to gravity, light from the CMB has warped while traveling past large, dense and heavy structures such as galaxy clusters. This is akin to looking at a grid pattern at the bottom of an empty swimming pool and noting the distortion caused as water is added.
This process is known as "gravitational lensing." Albert Einstein first suggested it as part of his theory of gravity, general relativity. By noting how the CMB has warped and distorted over time, scientists can learn a great deal about the evolution of matter over billions of years.
While the ACT data captures a snapshot of the CMB in its cosmic baby pictures, DESI provides scientists with a more recent record of a "grown-up" universe.
DESI does this by mapping the universe's three-dimensional structure, achieved by mapping the distribution of millions of galaxies, particularly luminous red galaxies (LRGs). Using these galaxies as "cosmic landmarks," scientists can reconstruct how matter has dispersed over cosmic time."The LRGs from DESI are like a more recent picture of the universe, showing us how galaxies are distributed at varying distances," Kim said. "It's a powerful way to see how structures have evolved from the CMB map to where galaxies stand today."Putting together ACT CMB lensing maps and DESI LRG data is like browsing through a photo album showing the development of an infant to an adult, but for the cosmos.
Browsing this cosmic photo album, the team noticed a small discrepancy. The "clumpiness" of matter the team calculated in later eras of the cosmos doesn't match theoretical predictions.Though the discrepancy isn't quite large enough to suggest entirely new physics are at play, it does suggest that cosmic structures haven't quite evolved in the way early-universe models would suggest. The results also hint that the universe's structural growth may have slowed in ways current models don't fully explain.
"What we found was that, for the most part, the story of structure formation is remarkably consistent with the predictions from Einstein's gravity," Madhavacheril said. "We did see a hint for a small discrepancy in the amount of expected clumpiness in recent epochs, around four billion years ago, which could be interesting to pursue."
Related Stories:
— 'Mind-blowing' dark energy instrument results show Einstein was right about gravity — again
— In a way, Space.com and the dark universe grew up together
— Dark energy could be getting weaker, suggesting the universe will end in a 'Big Crunch'
The researchers behind this work intend to continue this line of inquiry, but while utilizing more powerful upcoming telescopes, which should provide them with more precise measurements.
The team's research was published on Dec. 10, 2024, in the Journal of Cosmology and Astroparticle Physics.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
8 minutes ago
- Yahoo
Pacific spiny lumpsucker: The adorable little fish with a weird suction cup resembling human teeth
When you buy through links on our articles, Future and its syndication partners may earn a commission. QUICK FACTS Name: Pacific spiny lumpsucker (Eumicrotremus orbis) Where it lives: Northern Pacific, from Washington to Japan and north into the Bering Sea What it eats: Small fish, jellyfish, ctenophores, crustaceans, polychaetes Pacific spiny lumpsuckers' tiny, plump bodies and adorable appearance make them essentially wild kawaii. They are awkward swimmers, so to avoid being swept off by currents in their coastal homes, their pelvic fin has evolved to act as a suction cup, enabling them to anchor themselves to a stable surface. At just 1 to 3 inches (2.5 to 7.6 centimeters) long, they are the smallest of the 27 species of lumpsuckers, also called lumpfish, some of which can grow as long as two feet (61 cm). Lumpfish are in the same order, Scorpaeniformes, as blobfish, sea robins and stonefish. Pacific spiny lumpsuckers are small, globular fish with extra-small fins which they flap wildly to get around. It makes them able-but-awkward swimmers. Living close to the coast and facing the pulls of tides and strong currents, their pelvic fins are fused to form a surprisingly strong sucker disc which lets them attach to rocks, coral or kelp, and, in aquariums, even to the side of a tank. These sucker discs are a bit fearsome to look at from the underside – like a lamprey with a circle of human teeth. That's because, like our teeth, those of the Pacific spiny lumpsucker are made from enamel. The disc also emits a green and yellow glow — though the reasons for this are not known. Males are usually red (see 'concerned strawberries') and glow red under ultraviolet light, while females are usually green to brown and don't glow under UV rays. RELATED STORIES —Pelican eel: The midnight zone 'gulper' with a giant mouth to swallow animals bigger than itself —Pearlfish: The eel-like fish that lives up a sea cucumber's butt —Pigbutt worm: The deep-sea 'mystery blob' with the rump of a pig and a ballooned belly When it's time to reproduce, only the males settle down. They stake out a territory, usually a shallow depression in warmer water where the females lay their eggs. The male fertilizes them and then she leaves and he tends to and guards the next generation from lumpsuckers don't yet have a defense the adults have — rows of enamel bumps called odontodes covering their bodies, including that toothy-looking circle on their undersides. Eventually, they will grow odontodes in spiral rows all around their bodies to protect them against predators and collisions with rough surfaces.
Yahoo
2 hours ago
- Yahoo
June's full 'Strawberry Moon' illuminates the night sky next week: Here's how to see it
When you buy through links on our articles, Future and its syndication partners may earn a commission. This month's full "Strawberry Moon" graces the night sky on June 11, putting on a spectacular show as the fully-lit disk of Earth's natural satellite rides low over the southeastern horizon. A full moon occurs each month when the moon is positioned opposite the sun in Earth's sky, which allows the lunar disk to be fully lit from our perspective. June's full moon is commonly referred to as the "Strawberry Moon" in America, but the nickname isn't a reference to its color (though there's a decent chance it will take on a yellow-orange hue when near the horizon due to our atmosphere's habit of scattering certain wavelengths of light). Rather, the evocative name is thought to have been coined by the Native American Algonquian tribes in reference to the short strawberry harvesting season that falls around this time of year, according to the Old Farmer's Almanac. Other cultures have dubbed the event the Blooming Moon, Green Corn Moon, Birth Moon and Hatching moon, to name a few. Regardless of what you call it, one thing is certain: June's full moon is sure to put on a spectacular display when it lights up the night sky next week. This month's full moon phase will occur during the early hours of June 11 for viewers in New York, at 3:44 a.m. EDT (0744 GMT). The exact timing of the event will vary depending on your location on Earth, so be sure to check a trusted website such as for specifics about your locale. The lunar disk will appear fully lit to stargazers across America when it rises above the southeastern horizon at sunset on June 10, marking the best opportunity for the astrophotography community to capture the Strawberry Moon close to the horizon. Earth's natural satellite will appear particularly large to the naked eye at moonrise thanks to the little-understood "moon illusion," a strange effect wherein the human brain convinces us that objects are larger than they actually are when in close proximity to the horizon. Each year, June's full moon treads a predictably low path across the spring sky due to its close proximity to the summer solstice — the time of the year when the sun is at its highest. This year's Strawberry Moon will ride exceptionally low — the lowest in decades according to stargazing site — thanks in part to a phenomenon that sees the moon's tilted orbit dragged around by the sun's gravitational influence. Editor's Note: If you snap a picture of the full 'Strawberry Moon' and want to share it with readers, then please send your photo along with comments about the shoot, your name and location to spacephotos@
Yahoo
5 hours ago
- Yahoo
Scientists Calculate That the Entire Big Bang Must Have Taken Place Inside a Black Hole
The standard model of cosmology may be the best explanation we've got for why the universe is the way it is and how it all came to be. But it's not the only explanation. Enter black hole cosmology. It's a radical idea which proposes that the Big Bang — the rapid unraveling of an infinitely dense point, believed to have given birth to the cosmos as we know it — actually took place in a black hole, which itself formed inside a larger "parent" universe. Ergo, all of us — and every star, planet, galaxy, and internet rando — are living inside one of these mysterious singularities. Enrique Gaztanaga, lead author of a new study published in the journal Physical Review D and a professor at the Institute of Cosmology and Gravitation at the University of Portsmouth, isn't the first to propose this controversial idea. But his team's research offers a new model for imagining how this hypothetical scenario took place. "Our calculations suggest the Big Bang was not the start of everything, but rather the outcome of a gravitational crunch or collapse that formed a very massive black hole — followed by a bounce inside it," Gaztanaga wrote in an essay for The Conversation. Certainly, there are a lot of holes you could poke in the standard model. Why is there more matter than anti-matter, when the universe should be uniform? Why did the universe undergo a period of "cosmic inflation" in which it expanded at faster than light speeds, then stopped? And why does its present day rate of expansion appear to be different depending on how we measure it? Gaztanaga's main gripe seems to be with our current understanding of a singularity. To him, the idea of the universe starting as a point of infinite density is immensely unsatisfying. "This is not just a technical glitch; it's a deep theoretical problem that suggests we don't really understand the beginning at all," he wrote. Gaztanaga also takes aim at other convenient cosmological constructions like dark energy, which is intended to explain why the universe's expansion is mysteriously accelerating. This hypothetical force is thought to make up 68 percent of the universe but is completely unobservable, leaving room for different-minded scientists to call its existence into question. Rethinking singularities could neatly resolve many of these conundrums. We return to Gaztanaga's paper. "Gravitational collapse does not have to end in a singularity," he wrote for The Conversation. "Our maths show that as we approach the potential singularity, the size of the universe changes as a (hyperbolic) function of cosmic time." This is a bold claim. The consensus is that gravitational collapse — like a star imploding into a black hole — must result in an infinitely dense singularity. What Gaztanaga is arguing happens instead is that the collapse not only halt short of completely crushing the matter, but reverses course — a "bounce," in his terminology. "What emerges on the other side of the bounce is a universe remarkably like our own," Gaztanaga explains. "Even more surprisingly, the rebound naturally produces the two separate phases of accelerated expansion — inflation and dark energy — driven not by a hypothetical fields but by the physics of the bounce itself." It's a fascinating explanation, but there's a lot that remains to be proved. It relies on discounting some very well-established physics behind singularities. The standard model may not be perfect, but it's the standard for a reason. It'll take a lot more to dethrone it, and Gaztanaga is optimistic that future missions like the European Space Agency's ARRAKIHS, which will study invisible structures of dark matter to test the model, could reveal the answers we're looking for. More on cosmology: Astronomers Confused to Discover That a Bunch of Nearby Galaxies Are Pointing Directly at Us
