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Sunday, July 24, 2022

Halos and dark matter: A recipe for discovery

No, scientists still don’t know what dark matter is. But MSU scientists helped uncover new physics while looking for it.

Peer-Reviewed Publication

MICHIGAN STATE UNIVERSITY

EAST LANSING, Mich. – About three years ago, Wolfgang “Wolfi” Mittig and Yassid Ayyad went looking for the universe’s missing mass, better known as dark matter, in the heart of an atom.

Their expedition didn’t lead them to dark matter, but they still found something that had never been seen before, something that defied explanation. Well, at least an explanation that everyone could agree on. 

“It’s been something like a detective story,” said Mittig, a Hannah Distinguished Professor in Michigan State University’s Department of Physics and Astronomy and a faculty member at the Facility for Rare Isotope Beams, or FRIB

“We started out looking for dark matter and we didn’t find it,” he said. “Instead, we found other things that have been challenging for theory to explain.”

So the team got back to work, doing more experiments, gathering more evidence to make their discovery make sense. Mittig, Ayyad and their colleagues bolstered their case at the National Superconducting Cyclotron Laboratory, or NSCL, at Michigan State University. 

Working at NSCL, the team found a new path to their unexpected destination, which they detailed June 28 in the journal Physical Review Letters. In doing so, they also revealed interesting physics that’s afoot in the ultra-small quantum realm of subatomic particles. 

In particular, the team confirmed that when an atom’s core, or nucleus, is overstuffed with neutrons, it can still find a way to a more stable configuration by spitting out a proton instead.

Shot in the dark

Dark matter is one of the most famous things in the universe that we know the least about. For decades, scientists have known that the cosmos contains more mass than we can see based on the trajectories of stars and galaxies. 

For gravity to keep the celestial objects tethered to their paths, there had to be unseen mass and a lot of it — six times the amount of regular matter that we can observe, measure and characterize. Although scientists are convinced dark matter is out there, they have yet to find where and devise how to detect it directly.

“Finding dark matter is one of the major goals of physics,” said Ayyad,  a nuclear physics researcher at the Galician Institute of High Energy Physics, or IGFAE, of the University of Santiago de Compostela in Spain. 

Speaking in round numbers, scientists have launched about 100 experiments to try to illuminate what exactly dark matter is, Mittig said.

“None of them has succeeded after 20, 30, 40 years of research,” he said.

“But there was a theory, a very hypothetical idea, that you could observe dark matter with a very particular type of nucleus,” said Ayyad, who was previously a detector systems physicist at NSCL.

This theory centered on what it calls a dark decay. It posited that certain unstable nuclei, nuclei that naturally fall apart, could jettison dark matter as they crumbled.

So Ayyad, Mittig and their team designed an experiment that could look for a dark decay, knowing the odds were against them. But the gamble wasn’t as big as it sounds because probing exotic decays also lets researchers better understand the rules and structures of the nuclear and quantum worlds. 

The researchers had a good chance of discovering something new. The question was what that would be.

Help from a halo

When people imagine a nucleus, many may think of a lumpy ball made up of protons and neutrons, Ayyad said. But nuclei can take on strange shapes, including what are known as halo nuclei. 

Beryllium-11 is an example of a halo nuclei. It’s a form, or isotope, of the element beryllium that has four protons and seven neutrons in its nucleus. It keeps 10 of those 11 nuclear particles in a tight central cluster. But one neutron floats far away from that core, loosely bound to the rest of the nucleus, kind of like the moon ringing around the Earth, Ayyad said.

Beryllium-11 is also unstable. After a lifetime of about 13.8 seconds, it falls apart by what’s known as beta decay. One of its neutrons ejects an electron and becomes a proton. This transforms the nucleus into a stable form of the element boron with five protons and six neutrons, boron-11.

But according to that very hypothetical theory, if the neutron that decays is the one in the halo, beryllium-11 could go an entirely different route: It could undergo a dark decay.

In 2019, the researchers launched an experiment at Canada’s national particle accelerator facility, TRIUMF, looking for that very hypothetical decay. And they did find a decay with unexpectedly high probability, but it wasn’t a dark decay.

It looked like the beryllium-11’s loosely bound neutron was ejecting an electron like normal beta decay, yet the beryllium wasn’t following the known decay path to boron. 

The team hypothesized that the high probability of the decay could be explained if a state in boron-11 existed as a doorway to another decay, to beryllium-10 and a proton. For anyone keeping score, that meant the nucleus had once again become beryllium. Only now it had six neutrons instead of seven.

“This happens just because of the halo nucleus,” Ayyad said. “It’s a very exotic type of radioactivity. It was actually the first direct evidence of proton radioactivity from a neutron-rich nucleus.”

But science welcomes scrutiny and skepticism, and the team’s 2019 report was met with a healthy dose of both. That “doorway” state in boron-11 did not seem compatible with most theoretical models. Without a solid theory that made sense of what the team saw, different experts interpreted the team’s data differently and offered up other potential conclusions.

“We had a lot of long discussions,” Mittig said. “It was a good thing.”

As beneficial as the discussions were — and continue to be — Mittig and Ayyad knew they’d have to generate more evidence to support their results and hypothesis. They’d have to design new experiments.

The NSCL experiments

In the team’s 2019 experiment, TRIUMF generated a beam of beryllium-11 nuclei that the team directed into a detection chamber where researchers observed different possible decay routes. That included the beta decay to proton emission process that created beryllium-10.

For the new experiments, which took place in August 2021, the team’s idea was to essentially run the time-reversed reaction. That is, the researchers would start with beryllium-10 nuclei and add a proton. 

Collaborators in Switzerland created a source of beryllium-10, which has a half-life of 1.4 million years, that NSCL could then use to produce radioactive beams with new reaccelerator technology. The technology evaporated and injected the beryllium into an accelerator and made it possible for researchers to make a highly sensitive measurement.

When beryllium-10 absorbed a proton of the right energy, the nucleus entered the same excited state the researchers believed they discovered three years earlier. It would even spit the proton back out, which can be detected as signature of the process.

“The results of the two experiments are very compatible,” Ayyad said.

That wasn’t the only good news. Unbeknownst to the team, an independent group of scientists at Florida State University had devised another way to probe the 2019 result. Ayyad happened to attend a virtual conference where the Florida State team presented its preliminary results, and he was encouraged by what he saw. 

“I took a screenshot of the Zoom meeting and immediately sent it to Wolfi,” he said. “Then we reached out to the Florida State team and worked out a way to support each other.”

The two teams were in touch as they developed their reports, and both scientific publications now appear in the same issue of Physical Review Letters. And the new results are already generating a buzz in the community.

“The work is getting a lot of attention. Wolfi will visit Spain in a few weeks to talk about this,” Ayyad said.

An open case on open quantum systems

Part of the excitement is because the team’s work could provide a new case study for what are known as open quantum systems. It’s an intimidating name, but the concept can be thought of like the old adage, “nothing exists in a vacuum.”

Quantum physics has provided a framework to understand the incredibly tiny components of nature: atoms, molecules and much, much more. This understanding has advanced virtually every realm of physical science, including energy, chemistry and materials science.

Much of that framework, however, was developed considering simplified scenarios. The super small system of interest would be isolated in some way from the ocean of input provided by the world around it. In studying open quantum systems, physicists are venturing away from idealized scenarios and into the complexity of reality.

Open quantum systems are literally everywhere, but finding one that’s tractable enough to learn something from is challenging, especially in matters of the nucleus. Mittig and Ayyad saw potential in their loosely bound nuclei and they knew that NSCL, and now FRIB could help develop it.

NSCL, a National Science Foundation user facility that served the scientific community for decades, hosted the work of Mittig and Ayyad, which is the first published demonstration of the stand-alone reaccelerator technology. FRIB, a U.S. Department of Energy Office of Science user facility that officially launched on May 2, 2022 is where the work can continue in the future. 

“Open quantum systems are a general phenomenon, but they’re a new idea in nuclear physics,” Ayyad said. “And most of the theorists who are doing the work are at FRIB.”

But this detective story is still in its early chapters. To complete the case, researchers still need more data, more evidence to make full sense of what they’re seeing. That means Ayyad and Mittig are still doing what they do best and investigating.

“We’re going ahead and making new experiments,” said Mittig. “The theme through all of this is that it’s important to have good experiments with strong analysis.”

NSCL was a national user facility funded by the National Science Foundation, supporting the mission of the Nuclear Physics program in the NSF Physics Division.

Michigan State University (MSU) operates the Facility for Rare Isotope Beams (FRIB) as a user facility for the U.S. Department of Energy Office of Science (DOE-SC), supporting the mission of the DOE-SC Office of Nuclear Physics. Hosting what is designed to be the most powerful heavy-ion accelerator, FRIB enables scientists to make discoveries about the properties of rare isotopes in order to better understand the physics of nuclei, nuclear astrophysics, fundamental interactions and applications for society, including in medicine, homeland security and industry.

The U.S. Department of Energy Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of today’s most pressing challenges. For more information, visit energy.gov/science.

###

Michigan State University has been advancing the common good with uncommon will for more than 165 years. One of the world's leading research universities, MSU pushes the boundaries of discovery to make a better, safer, healthier world for all while providing life-changing opportunities to a diverse and inclusive academic community through more than 200 programs of study in 17 degree-granting colleges.

For MSU news on the Web, go to MSUToday. Follow MSU News on Twitter at twitter.com/MSUnews.

Monday, September 06, 2021

Scientists say a telescope on the Moon could advance physics — and they're hoping to build one

The Moon's lack of atmosphere and darkness could offers unique observations of the universe


By NICOLE KARLIS
PUBLISHED SEPTEMBER 5, 2021
View Of Earth's Moon Against The Sky At Night
 (Getty Images/Alexander Rieber/EyeEm)

Humans are reliant on the Moon for far more than most realize. The natural satellite that lights up the nighttime sky moderates Earth's tilt, creating a more stable and livable climate for us here on Earth. Without the Moon, there would be no seasons. And, the Moon also creates tides, which help move heat across the ocean from the equator to the poles.

In addition to the Moon's vital effects on Earth, this enchanting orb that has mesmerized humans since history began could play a critical role in furthering our understanding of the early universe, if only we can build an observatory there.

Interestingly, there is now a plan in development to do just that. In April 2020, the National Aeronautics and Space Administration (NASA) awarded the Lunar Crater Radio Telescope (LCRT) project $500,000 for further research and development. The premise of this project is that a massive radio telescope would be built by robots on the far side of the Moon in a 100-meter long, bowl-shaped crater with the mission of observing radio wavelengths that are 10 meters and longer.

One might wonder: why the Moon? Isn't this something that we can do here on Earth? The truth is there is only so much data we can gather about the universe from Earth, in part due to the own limitations of our planet when it comes to observing the night sky. Earth's (comparatively) dense atmosphere, light pollution and man-made electromagnetic radiation significantly hamper our ability to clearly observe the cosmos from our home planet.

In the case of radio telescopes, the Moon is an especially tantalizing choice for an observatory. On Earth, scientists are unable to observe cosmic radio waves that are longer than 10 meters because of the ionosphere — a layer of electrons, charged atoms and molecules, that surrounds Earth and protects us from harmful rays from the sun and other bad stuff in space. Earth's ionosphere essentially absorbs any radio wavelengths over 10 meters long. On the Moon, a lack of atmosphere and radiation could (on the far side) vastly improve observations.

"Because the ionosphere is such a strong source, even [by] putting a satellite around it we won't be able to observe any of those wavelengths . . . it basically drowns out all the signals [over 10 meters]," said Saptarshi Bandyopadhyay, a Robotics Technologist at NASA Jet Propulsion Laboratory and a the lead researcher on the LCRT project, in an interview with Salon. "So we need to go to a place where we are shielded from Earth, and the best place to go is to go to is the far side of the Moon.

An observatory on the far side of the Moon would have the added benefit of being perpetually shielded from electromagnetic noise from Earth. "The Moon is tidally locked, so only one side of the Moon faces us, and the other side of the Moon is always pointing away," Bandyopadhyay noted.

Bandyopadhyay argues there is an urgent need to better observe radio wavelengths over 10 meters, the kind that would have originated in the early days of our universe. Such a telescope might provide scientists with invaluable information about dark matter and dark energy.

These two substances mark one of the universe's most enduring mysteries. The existence of dark matter can be intuited by how it affects gravity, particularly the makeup and orbits of the largest-scale objects in the universe, galaxies. Yet no one knows exactly what dark matter it is, even though it makes up 27 percent of the universe's total mass and energy — far more than the 5 percent of the universe that "normal" matter, like planets and stars, comprises.

Dark energy, an ill-understood force that is responsible for the accelerating expansion of our universe, is estimated to comprise 68 percent of all matter and energy in the universe. JUST ANOTHER NAME FOR 'AETHYR'

"Right now, we have some ideas, some models of what happened at the time of the Big Bang, and then we have some idea of what the current universe looks like, where all the galaxies are, how they're moving away, and things like that, but they're not many large questions in the middle [that remain unanswered]," Bandyopadhyay said. "A good part of that region is not observable because we have never looked at the universe 10 meters or longer, and that's what we want to observe — we want to observe those 10 meters and longer wavelengths, so that we can understand things like, 'why is there dark energy and dark matter, what is the pattern, and then why is there so much more matter and so little antimatter in the universe?'"

Bandyopadhyay said scientists need to find answers to these questions before humanity makes "another giant leap in physics."

Such a leap in understanding of fundamental physics might be nearer than one might think. Bandyopadhyay noted that 100 years ago, scientists were just starting to understand nuclear energy. Perhaps dark energy could be used in unknown ways in the future — we just have to understand it first.

"We know the universe is made out of only 4% matter, and 95% of the universe is dark matter and dark energy, and we understand nothing about it," Bandyopadhyay said. "My personal thought is if we could at least observe those regions of the universe, where dark energy and dark matter is active, we might be able to piece together what dark energy and dark matter is."

"Maybe our grandchildren would be able to take advantage of dark matter for interstellar travel," he mused.

Bandyopadhyay said the thought is a little "science fiction"; but argues in the 1920s, people likely would have thought powering homes from nuclear plants would have been science fictional, too.

Of course, to assemble such a device on the Moon would not be easy. In the LCRT proposal, robots would build the massive radio telescope. In order to work well, its dish would have to be at least like 10 times longer than the longest wavelength they'd observe. Bandyopadhyay said the budget would need to be between $1 billion and $5 billion. Two space crafts would be needed: one to deliver the mesh wire of the telescope, a material change to adapt to operating on the Moon, and a second to deliver the DuAxel rovers which would build the dish over several days or weeks.

"It's going to be a long journey," Bandyopadhyay said. "I would be very surprised if we managed to launch before I retired and I'm a very young scientist right now, but if you see all the other missions that's the kind of time it takes."

There is precedent for building a radio telescope in a crater: the Arecibo Observatory in Puerto Rico, which collapsed due to neglect recently, operated for decades and provided valuable scientific data. As with the proposed LCRT, the Arecibo Observatory took advantage of the natural concavity of its resident crater to focus distant radio waves. However, unlike the proposed lunar observatory, the Arecibo Observatory was not constructed entirely by robots.

Notably, only one spacecraft has successfully soft landed on the Moon's far side, which was China's Chang'e 4. Still, the very possibility of putting a radio telescope on the Moon is closer than it has ever been before. Such an instrument could pave the way for different types of telescopes, including optical ones, to make home in other spots on the Moon, ultimately transforming humanity's view of the cosmos.

"Visual telescopes would also benefit from the lack of an atmosphere on the Moon," said Avi Loeb, the former chair of the astronomy department at Harvard University (2011-2020). "Atmospheric turbulence blurs and distorts images of sources in the sky when observing from Earth; X-rays cannot propagate through the Earth's atmosphere and can also be observed from the Moon, and finally, the Moon has no geological activity and so a LIGO-like gravitational wave detector would benefit greatly from the lack of seismic noise and the vacuum that is offered for free — eliminating the need for vacuum tubes as used in the terrestrial version."

NICOLE KARLIS is a staff writer at Salon. Tweet her @nicolekarlis.

Thursday, December 09, 2021

This faraway galaxy may be completely devoid of dark matter


By Mara Johnson-Groh
published 1 day ago

A galaxy without dark matter would upend fundamental theories about galaxy formation.

The galaxy AGC 114905 seems to be devoid of dark matter. In this image, the stellar emission is shown in blue; and green clouds show the neutral hydrogen gas. (Image credit: Javier Román & Pavel Mancera Piña, CC BY 4.0)

On the surface, a galaxy 250 million light-years from Earth seems like any other, but a deeper look reveals a puzzling quirk: It seems to have no dark matter.

If these galaxies are ultimately confirmed to be devoid of dark matter, it could upend fundamental theories about the making of galaxies (dark matter is considered essential to this process). And that, in turn, could rule out a leading candidate for the mysterious substance, called cold dark matter.

"In principle, galaxies like this shouldn't exist," said Pavel Mancera Piña, a doctoral candidate in astronomy at the University of Groningen in the Netherlands and an astronomer at ASTRON (the Netherlands Institute for Radio Astronomy), referring to the fact that dark matter is thought to be the glue that holds a galaxy's stars, gas and dust together. "We cannot effectively explain them with any existing theory," said Mancera Piña, who is the lead author of a new paper describing the findings.

The galaxy, called AGC 114905, is an ultradiffuse galaxy (UDG). These galaxies are faint; AGC 114905 is about the same size as the Milky Way but has 1,000 times fewer stars.

When Mancera Piña and his colleagues first looked at AGC 114905 in 2019 , they suspected it might not have dark matter because of how fast it was rotating. The speed at which a galaxy rotates reveals how much stuff it contains; the more massive a galaxy, the stronger its gravity and the faster it spins. By comparing the speed with how much stuff can be seen — the amount of stars, gas and dust — astronomers can work backward to figure out how much extra invisible stuff — dark matter — must be present to account for the speed of the galaxy.

But because the galaxy in question is so faint, they didn't have enough data initially to fully resolve the rotation speed to tell if it was totally devoid of dark matter. So they went back for a second look, compiling 40 hours of observations with the Very Large Array, a radio observatory in New Mexico.

Through their observations, which mapped the gas in the galaxy, the astronomers figured out how fast the gas was moving. This allowed them to figure out the galaxy's rotation speed and thus how much dark matter is present in the galaxy. But ultimately the researchers concluded that there doesn't seem to be any room for dark matter.

"That's what we were expecting, of course, but you never know," Mancera Piña said. "It was still a bit of a surprise."

Missing dark matter

In the past, astronomers have discovered some UDGs that are rich in dark matter and others lacking it, Live Science previously reported. Some of the latter type are found near more massive galaxies; this finding suggests they may have lost their dark matter through interactions with their larger nearby galaxies, whose gravity may have whisked the smaller galaxies' dark matter away. But considering AGC 114905 doesn't have any massive galaxies nearby, that explanation is unlikely, Mancera Piña said.

This poses a challenge to theories of galaxy formation, because dark matter is thought to be essential for their formation, as its gravity helps pull the relatively rarer normal material together. If there are galaxies with no dark matter, that implies dark matter may not be needed to form galaxies.

Studying AGC 114905 also gives astronomers a new way to test the nature of dark matter. Current theories of galaxy formation rely on a special type of dark matter called cold dark matter, but if those theories don't explain weird galaxies like AGC 114905, then maybe cold dark matter isn't workable either.

"We have been trying to understand what dark matter is for the last 50 years, but we seem to have reached some kind of dead end," Mancera Piña said. By carefully studying this galaxy and others like it, the astronomers might be able to provide constraints on what dark matter might be like, if it's not cold dark matter. In the study, the researchers also applied models of an alternative theory to dark matter called Modified Newtonian dynamics, or MOND, to see if that could explain the galaxy's unique characteristics. However, this theory wasn't able to reconcile the speed of the galaxy either.

Pieter van Dokkum, an astronomer atYale University who has studied dark matter-deficient UDGs but was not involved with the new work, said he thinks the new findings are promising and significant, but that more research will be required for astronomers to be sure the galaxy is truly devoid of dark matter.

"There will be a lot of discussion," van Dokkum said. "Extraordinary claims require extraordinary evidence."

The study authors plan to study AGC 114905 further and are gathering observations of other UDGs that might be free of dark matter.

The findings were published on Nov. 30 to the preprint server arXiv and have been accepted for publication in the journal Monthly Notices of the Royal Astronomical Society.

Originally published on Live Science.


SEE 






Saturday, March 16, 2024

BEEN SAYING THIS FOR YEARS

New research suggests that our universe has no dark matter


The current theoretical model for the composition of the universe is that it’s made of ‘normal matter,’ ‘dark energy’ and ‘dark matter.’ A new uOttawa study challenges this




UNIVERSITY OF OTTAWA

New research suggests that our universe has no dark matter 

IMAGE: 

“THE STUDY'S FINDINGS CONFIRM THAT THE UNIVERSE DOES NOT REQUIRE DARK MATTER TO EXIST”

RAJENDRA GUPTA

— PHYSICS PROFESSOR AT THE FACULTY OF SCIENCE, UOTTAWA

view more 

CREDIT: UNIVERSITY OF OTTAWA




The current theoretical model for the composition of the universe is that it’s made of ‘normal matter,’ ‘dark energy’ and ‘dark matter.’ A new uOttawa study challenges this.

A University of Ottawa study published today challenges the current model of the universe by showing that, in fact, it has no room for dark matter.

In cosmology, the term “dark matter” describes all that appears not to interact with light or the electromagnetic field, or that can only be explained through gravitational force. We can’t see it, nor do we know what it’s made of, but it helps us understand how galaxies, planets and stars behave.

Rajendra Gupta, a physics professor at the Faculty of Science, used a combination of the covarying coupling constants (CCC) and “tired light” (TL) theories (the CCC+TL model) to reach this conclusion. This model combines two ideas — about how the forces of nature decrease over cosmic time and about light losing energy when it travels a long distance. It’s been tested and has been shown to match up with several observations, such as about how galaxies are spread out and how light from the early universe has evolved.

This discovery challenges the prevailing understanding of the universe, which suggests that roughly 27% of it is composed of dark matter and less than 5% of ordinary matter, remaining being the dark energy. 

Challenging the need for dark matter in the universe

“The study's findings confirm that our previous work (“JWST early Universe observations and ΛCDM cosmology”) about the age of the universe being 26.7billionyears has allowed us to discover that the universe does not require dark matter to exist,” explains Gupta. “In standard cosmology, the accelerated expansion of the universe is said to be caused by dark energy but is in fact due to the weakening forces of nature as it expands, not due to dark energy.”

“Redshifts” refer to when light is shifted toward the red part of the spectrum. The researcher analyzed data from recent papers on the distribution of galaxies at low redshifts and the angular size of the sound horizon in the literature at high redshift.

“There are several papers that question the existence of dark matter, but mine is the first one, to my knowledge, that eliminates its cosmological existence while being consistent with key cosmological observations that we have had time to confirm,” says Gupta.

By challenging the need for dark matter in the universe and providing evidence for a new cosmological model, this study opens up new avenues for exploring the fundamental properties of the universe.

The study, Testing CCC+TL Cosmology with Observed Baryon Acoustic Oscillation Features,was published in the peer-reviewed Astrophysical Journal.

 

Wednesday, February 15, 2023

1st observational evidence linking black holes to dark energy

Peer-Reviewed Publication

UNIVERSITY OF HAWAII AT MANOA

Supermassive black hole 

IMAGE: ARTIST'S IMPRESSION OF A SUPERMASSIVE BLACK HOLE. COSMOLOGICAL COUPLING ALLOWS BLACK HOLES TO GROW IN MASS WITHOUT CONSUMING GAS OR STARS. view more 

CREDIT: UH MĀNOA

Searching through existing data spanning 9 billion years, a team of researchers led by scientists at University of Hawaiʻi at Mānoa has uncovered the first evidence of "cosmological coupling" –a newly predicted phenomenon in Einstein's theory of gravity, possible only when black holes are placed inside an evolving universe.

Astrophysicists Duncan Farrah and Kevin Croker led this ambitious study, combining Hawaiʻi's expertise in galaxy evolution and gravity theory with the observation and analysis experience of researchers across nine countries to provide the first insight into what might exist inside real black holes.

"When LIGO heard the first pair of black holes merge in late 2015, everything changed," said Croker. "The signal was in excellent agreement with predictions on paper, but extending those predictions to millions, or billions of years?  Matching that model of black holes to our expanding universe? It wasn't at all clear how to do that."

The team has recently published two papers, one in The Astrophysical Journal and the other in The Astrophysical Journal Letters, that studied supermassive black holes at the hearts of ancient and dormant galaxies.

The first paper found that these black holes gain mass over billions of years in a way that can't easily be explained by standard galaxy and black hole processes, such as mergers or accretion of gas.

The second paper finds that the growth in mass of these black holes matches predictions for black holes that not only cosmologically couple, but also enclose vacuum energy—material that results from squeezing matter as much as possible without breaking Einstein's equations, thus avoiding a singularity.

With singularities absent, the paper then shows that the combined vacuum energy of black holes produced in the deaths of the universe's first stars agrees with the measured quantity of dark energy in our universe.

“We're really saying two things at once: that there's evidence the typical black hole solutions don't work for you on a long, long timescale, and we have the first proposed astrophysical source for dark energy,'' said Farrah, lead author of both papers.

“What that means, though, is not that other people haven't proposed sources for dark energy, but this is the first observational paper where we're not adding anything new to the universe as a source for dark energy: black holes in Einstein's theory of gravity are the dark energy.''

These new measurements, if supported by further evidence, will redefine our understanding of what a black hole is.

Nine billion years ago
In the first study, the team determined how to use existing measurements of black holes to search for cosmological coupling. 

"My interest in this project was really born from a general interest in trying to determine observational evidence that supports a model for black holes that works regardless of how long you look at them," Farrah said. "That's a very, very difficult thing to do in general, because black holes are incredibly small, they're incredibly difficult to observe directly, and they are a long, long way away." 

Black holes are also hard to observe over long timescales. Observations can be made over a few seconds, or tens of years at most—not enough time to detect how a black hole might change throughout the lifetime of the universe. To see how black holes change over a scale of billions of years is a bigger task. 

"You would have to identify a population of black holes and identify their distribution of mass billions of years ago. Then you would have to see the same population, or an ancestrally connected population, at present day and again be able to measure their mass," said co-author Gregory Tarlé, a physicist at University of Michigan. "That's a really difficult thing to do." 

Because galaxies can have life spans of billions of years, and most galaxies contain a supermassive black hole, the team realized that galaxies held the key, but choosing the right types of galaxy was essential. 

"There were many different behaviors for black holes in galaxies measured in the literature, and there wasn't really any consensus," said study co-author Sara Petty, a galaxy expert at NorthWest Research Associates. "We decided that by focusing only on black holes in passively evolving elliptical galaxies, we could help to sort this thing out." 

Elliptical galaxies are enormous and formed early. They are fossils of galaxy assembly. Astronomers believe them to be the final result of galaxy collisions, enormous in size with upwards of trillions of old stars. 

By looking at only elliptical galaxies with no recent activity, the team could argue that any changes in the galaxies' black hole masses couldn't easily be caused by other known processes. Using these populations, the team then examined how the mass of their central black holes changed throughout the past 9 billion years. 

If mass growth of black holes only occurred through accretion or merger, then the masses of these black holes would not be expected to change much at all. However if black holes gain mass by coupling to the expanding universe, then these passively evolving elliptical galaxies might reveal this phenomenon. 

The researchers found that the further back in time they looked, the smaller the black holes were in mass, relative to their masses today. These changes were big: The black holes were anywhere from 7 to 20 times larger today than they were 9 billion years ago—big enough that the researchers suspected cosmological coupling could be the culprit. 

Unlocking black holes 

In the second study, the team investigated whether the growth in black holes measured in the first study could be explained by cosmological coupling alone. 

"Here's a toy analogy. You can think of a coupled black hole like a rubber band, being stretched along with the universe as it expands," said Croker. "As it stretches, its energy increases. Einstein's E = mc2 tells you that mass and energy are proportional, so the black hole mass increases, too." 

How much the mass increases depends on the coupling strength, a variable the researchers call k

"The stiffer the rubber band, the harder it is to stretch, so the more energy when stretched. In a nutshell, that's k," Croker said. 

Because mass growth of black holes from cosmological coupling depends on the size of the universe, and the universe was smaller in the past, the black holes in the first study must be less massive by the correct amount in order for the cosmological coupling explanation to work. 

The team examined five different black hole populations in three different collections of elliptical galaxies, taken from when the universe was roughly one half and one third of its present size. In each comparison, they measured that k was nearly positive 3. 

The first observational link

In 2019, this value was predicted for black holes that contain vacuum energy, instead of a singularity by Croker, then a graduate student, and Joel Weiner, a UH Mānoa mathematics professor. 

The conclusion is profound: Croker and Weiner had already shown that if k is 3, then all black holes in the universe collectively contribute a nearly constant dark energy density, just like measurements of dark energy suggest. 

Black holes come from dead large stars, so if you know how many large stars you are making, you can estimate how many black holes you are making and how much they grow as a result of cosmological coupling. The team used the very latest measurements of the rate of earliest star formation provided by the James Webb Space Telescope and found that the numbers line up. 

According to the researchers, their studies provide a framework for theoretical physicists and astronomers to further test—and for the current generation of dark energy experiments such as the Dark Energy Spectroscopic Instrument and the Dark Energy Survey—to shed light on the idea. 

"If confirmed this would be a remarkable result, pointing the way towards the next generation of black hole solutions," said Farrah.

Croker added, "This measurement, explaining why the universe is accelerating now, gives a beautiful glimpse into the real strength of Einstein's gravity. A chorus of tiny voices spread throughout the universe can work together to steer the entire cosmos. How cool is that?"

  

Researchers studied elliptical galaxies like Messier 59 to determine if the mass of their central black holes changed throughout the past 9 billion years. The smooth distribution of light is billions of stars.

CREDIT

ESA/Hubble & NASA, P. Cote


Caldwell 53 (NGC 3115) is most notable for the supermassive black hole that can be found at its center.

CREDIT

NASA, ESA, and J. Erwin (University of Alabama)

Measurement of coupling strength k by comparing black hole masses in 5 different collections of ancient elliptical galaxies to the black holes in elliptical galaxies today. Measurements cluster around k = 3, implying that black holes contain vacuum energy, instead of a singularity.

CREDIT

Farrah, et al. 2023 [the ApJ Letter]

Thursday, January 12, 2023

Nuclear reactor experiment rules out one dark matter hope

Pierre Celerier and Daniel Lawler
Thu, 12 January 2023 


It was an anomaly detected in the storm of a nuclear reactor so puzzling that physicists hoped it would shine a light on dark matter, one of the universe's greatest mysteries.

However new research has definitively ruled out that this strange measurement signalled the existence of a "sterile neutrino", a hypothetical particle that has long eluded scientists.

Neutrinos are sometimes called "ghost particles" because they barely interact with other matter -- around 100 trillion are estimated to pass through our bodies every second.

Since neutrinos were first theorised in 1930, scientists have been trying to nail down the properties of these shape-shifters, which are one of the most common particles in the universe.

They appear "when the nature of the nucleus of an atom has been changed", physicist David Lhuillier of France's Atomic Energy Commission told AFP.

That could happen when they come together in the furious fusion in the heart of stars like our Sun, or are broken apart in nuclear reactors, he said.

There are three confirmed flavours of neutrino: electron, muon and tau.

However physicists suspect there could be a fourth neutrino, dubbed "sterile" because it does not interact with ordinary matter at all.

In theory, it would only answer to gravity and not the fundamental force of weak interactions, which still hold sway over the other neutrinos.

The sterile neutrino has a place ready for it in theoretical physics, "but there has not yet been a clear demonstration that is exists," he added.

- Dark matter candidate -


So Lhuillier and the rest of the STEREO collaboration, which brings together French and German scientists, set out to find it.

Previous nuclear reactor measurements had found fewer neutrinos than the amount expected by theoretical models, a phenomenon dubbed the "reactor antineutrino anomaly".

It was suggested that the missing neutrinos had changed into the sterile kind, offering a rare chance to prove their existence.

To find out, the STEREO collaboration installed a dedicated detector a few metres away from a nuclear reactor used for research at the Laue–Langevin institute in Grenoble, France.

After four years of observing more than 100,000 neutrinos and two years analysing the data, the verdict was published in the journal Nature on Wednesday.

The anomaly "cannot be explained by sterile neutrinos," Lhuillier said.

But that "does not mean there are none in the universe", he added.

The experiment found that previous predictions of the amount of neutrinos being produced were incorrect.

But it was not a total loss, offering a much clearer picture of neutrinos emitted by nuclear reactors.

This could help not just with future research, but also for monitoring nuclear reactors.

Meanwhile, the search for the sterile neutrino continues. Particle accelerators, which smash atoms, could offer up new leads.

Despite the setback, interest could remain high because sterile neutrinos have been considered a suspect for dark matter, which makes up more than quarter of the universe but remains shrouded in mystery.

Like dark matter, the sterile neutrino does not interact with ordinary matter, making it incredibly difficult to observe.

"It would be a candidate which would explain why we see the effects of dark matter -- and why we cannot see dark matter," Lhuillier said.

LA REVUE GAUCHE - Left Comment: Search results for DARK MATTER