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Physicists Explore the Moments When Nature’s Strongest Forces Diminish

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STAR detector of the relativistic heavy ion collider

Brookhaven National Laboratory

We are making strides toward comprehending when the powerful nuclear force weakens its influence on the most basic components of matter, causing quarks and gluons within particles to suddenly morph into a hot soup of particles.

There exist unique combinations of temperature and pressure where all three phases of water (liquid, ice, and vapor) coexist simultaneously. For years, scientists have sought similar “critical points” in matter impacted by the potent nuclear force that binds quarks and gluons into protons and neutrons.

In a particle collider, when ions collide, the strong force is disrupted, resulting in a state where quarks and gluons form a soup-like “quark-gluon plasma.” However, it remains uncertain if there is a tipping point preceding this transition. Shinto Researchers at the Lawrence Berkeley National Laboratory in California are getting closer to unraveling this mystery.

They assessed the number and distribution of particles produced after the collision of two high-energy gold ions at the Relativistic Heavy Ion Collider at Brookhaven National Laboratory in New York. Dong mentioned they were essentially attempting to formulate a phase diagram for quarks and gluons, depicting what types of matter are generated by strong forces under varied conditions. Although the new experiment did not definitively locate the critical point on this diagram, it significantly narrowed the possible area for its existence.

The phase diagram indicates a region where the material gradually “melts” into plasma, akin to butter softening on a countertop, but a critical point would correspond to a more sudden transition, similar to a chunk of ice unexpectedly forming in liquid water. Agnieszka Sorensen from the Rare Isotope Beam Facility in Michigan, which was not part of the study, stated that this new experiment not only guides researchers in pinpointing this critical point but also uncovers which particle properties might best indicate its presence.

Claudia Ratti from the University of Houston in Texas emphasized that many researchers eagerly anticipated the new analysis due to its precision, which surpasses that of previous measurements, particularly in parts of phase diagrams difficult to theoretically compute. She noted that several predictions regarding the critical point’s location have recently converged, and the challenge for experimenters will now be to analyze data at even lower collision energies that align with these predictions.

Dong remarked that the clear detection of the tipping point would mark a generational milestone. This is significant as the only fundamental force suspected of possessing a critical point is the strong force, which has played a crucial role in the universe’s formation. It governs the characteristics of the hot, dense matter created shortly after the Big Bang and continues to influence the structure of neutron stars. Dong concluded that collider experiments like this one could deepen our understanding of these exotic celestial objects once the strong force phase diagram is finalized.

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Source: www.newscientist.com

Astronomers continue to debate the strongest evidence for extraterrestrial life

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Impressions of the artists of Planet K2-18B and its host star

ESA/Hubble, M. Kornmesser

Astronomers claim they have seen the most powerful evidence ever for living on another planet. However, other astronomers are cautioning until the findings are verified by other groups, allowing alternative, nonbiological explanations to be excluded.

“These are the first hints we see about the alien world we probably live in.” Nick Madhusdan We held a press conference at Cambridge University on March 15th.

Astronomers first discovered the Exoplanet K2-18B in 2015, quickly establishing it as a promising place for searching for life. Planets orbiting stars about eight times more than Earth, 124 light years away from us, sit in a habitable zone of stars where liquid water is present. Further observations in 2019 found evidence of water vapor. This led to the suggestion that, although not all astronomers agreed, the planet could be covered in oceans sitting under a hydrogen-rich atmosphere.

In 2023, Madhusudhan and his colleagues used James Webb Space Telescope (JWST) instruments to examine the atmosphere of the near-infrared light K2-18B, again finding evidence of water vapor and methane. However, they also found appetizing hints for dimethyl sulfide (DMS), a molecule that is produced exclusively by organisms on Earth, primarily by marine phytoplankton. However, the signs of DMS were very weak and many The astronomers argued Stronger evidence is needed to be certain about the existence of molecules.

Currently, Madhusudhan and his colleagues use different instruments to observe the K2-18b than the mid-infrared camera JWST. They discovered a much stronger signal against DMS and a molecule that could be called dimethyldisulfide (DMDS).

“What we’re finding is a line of independent evidence in different wavelength ranges with different equipment that can potentially biological activity on the planet,” Madhusdan said.

The team argues that detection of DMS and DMD is at three sigma levels of statistical significance. This corresponds to a 1/100 chance that a pattern of data like this will become absorption. In physics, the standard threshold for accepting something as a true discovery is five sigmas, which corresponds to 1-3.5 million chances that data is a coincidence.

Nicholas Wargan The NASA Ames Research Center in California says the evidence is more convincing than the 2023 results, but it should be verified by other groups. When data is published next week, other researchers can begin to review the findings, but this could take weeks or months as JWST data is difficult to interpret. “It’s not just about downloading data and checking if there’s a DMS. It’s this extremely complicated process,” says Wogan.

Other scientists are more skeptical of the findings. “These new JWST observations do not provide compelling evidence that DMS or DMD exists in the atmosphere of K2-18B.” Ryan McDonald At the University of Michigan. “We have a juvenile chase wolf situation in the K2-18B, where multiple previous 3-sigma detections have completely disappeared when subjected to closer scrutiny.

Madhusudhan and his team estimate that further 16 to 24 hours of further observations at the JWST will help reach 5-sigma levels, but observing the planet’s atmosphere means that this cannot be guaranteed.

“The relative size of the atmosphere compared to the planet’s size is pretty close to the thickness of the apple’s skin on top of the apple, which is what we’re trying to measure.” Thomas Beatty At the University of Wisconsin-Madison, where I was not part of the learning team. Wogan adds that reaching five sigmas may be fundamentally impossible due to the amount of noise in the data.

But if further observations prove that this is a real discovery, it would be a “risqué progress,” says Beatty. “Ignoring whether it was actually being produced for a moment, I said that ten years ago it is evidence of life in a planetary atmosphere that can certainly host it.”

Madhusudhan and his colleagues calculate that the potential concentration of DMS and DMD in K2-18B appears to be over ten parts, thousands of times more than the concentrations in the Earth’s atmosphere. This could show far more biological activity than Earth if the signal turns out to be correct, but establishing that chemicals have biological origins requires more work, he says.

“We need to be very careful,” Madhusdan said. “At this stage, when you detect DMS and DMD, you can’t claim it’s for life. Let’s be very clear about that.

It could take some time to eliminate another mechanism, Wogan says. “This kind of thing hasn’t been studied in practice. In a hydrogen-rich atmosphere, DM doesn’t know tons about it. It requires a lot of work.”

The difficulty in proving that it has no nonbiological explanations is that it could potentially put K2-18B in the category of viable biosignature candidates over a long period of time. Sarah Seager At Massachusetts Institute of Technology. “It could remain in that category for decades, because the problem will not be completely solved by providing limited data deplanets,” she says.

However, Madhusudhan says this discovery is important whether it comes from life or not. “This was a revolutionary moment, and we were able to come from a single cell life, not just as astronomers, but also for our species, from a single cell life billions of years ago, to a highly technological civilization where we could peer into the atmosphere of another planet and find evidence of actual biological activity,” he said.

The Mystery of the Universe: Cheshire, England

Spend a weekend with some of the brightest minds of science. Explore the mystery of the universe in an exciting program that includes an excursion to see the iconic Lovell telescope.

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Source: www.newscientist.com

Researchers find that melting ice sheets are causing a reduction in the speed of the world’s strongest ocean currents

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Antarctic Circulating Current (ACC), which is more than four times as strong as the Gulf Stream, is the world’s strongest ocean current and plays an unbalanced role in the climate system due to its role as a major basin conduit. Scientists at the University of Melbourne and the Research Centre in Nordic Norway have shown that ACC will slow by about 20% by 2050 in high carbon emission scenarios. This influx of freshwater into the southern ocean is expected to alter the properties such as the density (salinity) of the ocean and its circulation patterns.

Sohail et al. High-resolution ocean and sea ice simulations of ocean currents, heat transport, and other factors were analyzed to diagnose the effects of temperature changes, saltiness, and wind conditions. Image credit: Sohail et al. , doi: 10.1088/1748-9326/adb31c.

“The oceans are extremely complex, finely balanced,” says Dr. Bishakhdatta Gayen, liquid mechanic at the University of Melbourne.

“If this current ‘engine’ collapses, serious consequences, including more climate change, including extreme extreme climate variability in certain regions, will accelerate global warming due to a decline in the ability of the ocean to function as a carbon sink. “

The ACC acts as a barrier to invasive species, like the southern burkelp and marine vectors such as shrimp and mollusks, which travel in the current from other continents reaching Antarctica.

If this current slows and weakens, it is more likely that such species will head towards the fragile Antarctica, potentially serious effects on food webs, which could change the available diet of Antarctic penguins, for example.

The ACC is an important part of the marine conveyor belt around the world, moving water around the world and linking the Atlantic, Pacific and Indian seas. These are the main mechanisms of exchange of heat, carbon dioxide, chemicals and biology throughout these basins.

In their study, the authors used Gadi, the fastest supercomputer in Australia located on the Access National Research Infrastructure.

They discovered that transport of seawater from the surface to the deepest could also be slower in the future.

“If ice melting accelerates as predicted by other studies, slowdowns are predicted to be similar in low emission scenarios,” Dr. Sohail said.

“The 2015 Paris Agreement aims to limit global warming to 1.5 degrees Celsius above pre-industrial levels.”

“Many scientists agree that we have already reached this 1.5 degree target, which could have an impact on the melting of Antarctic ice, making it even hotter.”

“Cooperative efforts to limit global warming (by reducing carbon emissions) will limit the melting of Antarctic ice and avoid the expected slowdown in ACC.”

This study reveals that the effects of ice melting and ocean warming on ACC are more complicated than previously thought.

“The melted ice sheets throw a large amount of fresh water from salt water into the salty sea.”

“This sudden change in ocean salinity has a series of results, including weakening of subsidence to the depths of surface seawater (called Antarctic bottom water), and based on this study, it includes weakening of the powerful marine jets surrounding Antarctica,” Dr. Gayen said.

study Published in the journal Environmental Survey Letter.

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Taimoor Sohail et al. 2025. Decreasing the polar current in the Antarctic due to polarization. environment. res. Rent 20, 034046; doi:10.1088/1748-9326/adb31c

Source: www.sci.news

The Strongest Material in the Universe: Ultra-Dense Cosmic “Pasta”

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The concept of “strength” in materials refers to their ability to withstand deformation caused by external forces.

Typically, the strongest materials are the densest ones because atoms in close proximity offer greater resistance to compression. However, factors like structural properties can also influence strength, leading to exceptions like graphene, which is the strongest natural material despite not being the densest like osmium.

Some high-density states of matter, formed when massive stars collapse, are incredibly strong compared to ordinary matter. For instance, white dwarf stars have a structure composed of carbon and oxygen nuclei surrounded by electrons experiencing degeneracy pressure, preventing further compression.

However, in cases of extreme density like neutron stars, the degeneracy pressure of densely packed nuclei and free protons and neutrons overcomes electron degeneracy pressure, halting further collapse.

Nuclear pasta is created by the conflicting forces of protons and neutrons, resulting in various shapes. This tightly bound and incredibly strong material is believed to be the most robust substance in the universe. – Credit: Mark Garlick

The material within neutron stars is about 100 trillion times denser than anything found on Earth. While the exact structure is complex and uncertain, a theorized thin layer within the star undergoes a transition from normal to ultra-dense matter, forming different shapes known as nuclear pasta.

Scientists consider this ultra-dense material to be the strongest substance in the universe, estimated to be at least 10 billion times stronger than steel.

This article addresses the question (from Colin Davids of Bridgewater): “What is the strongest material in the universe?”

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