Space, to the naked eye, appears still, tranquil. But to scientists viewing it through increasingly powerful telescopes, it looks turbulent, with violent streams of gas buffeting dusty materials that form fascinating shapes, then disperse.Now an international team of astronomers has employed the Atacama Large Millimeter/submillimeter Array (ALMA) to get a better view of this action. ALMAs amazingly high resolution has sharpened the view of the tempestuous churn in Milky Ways central zone. This area, surrounding the supermassive black hole Sagittarius A* (Sgr A*), acts as a kind of galactic mixing bowl, swirling gas and dust and emitting shock waves ripples. The astronomers observing this activity report a new structure in the journal Astronomy & Astrophysics: long, thin filaments as an important byproduct of space material circulation.Spying on Space TornadoesWe can envision these as space tornados: they are violent streams of gas, they dissipate shortly, and they distribute materials into the environment efficiently," Xing Lu, a research professor at Shanghai Astronomical Observatory and an author of research paper, said in a press release. The general notion that the core of our galaxy, called the Central Molecular Zone (CMZ) is an active place is not a new one. The forces that power the Mixmaster of the Milky Way have long remained a mystery. Observing interaction between this turbulent environment and the slim filaments produced, as shocks ripple through, provides a more complete view of the cyclical processes within the CMZ. The dynamic interactions within this turbulent environment and the slim filaments it produced shows a clearer movie of the action. But the presence of the filaments provides another mystery.Unlike any objects we know, these filaments really surprised us, Kai Yang, an astrophysicist from Shanghai Jiao Tong University in China and an author of the paper, said in a press release. Since then, we have been pondering what they are.Read More: 10 Facts You May Not Know About the Milky WayProposing a New ModelThe slim filaments dont fit into models of outflows from such systems, therefore they dont match the profile of previously discovered dense gas filaments. Thus, they do not fit the profile of other previously discovered types of dense gas filaments. They also do not appear to be associated with dust emission.Yangs team hypothesizes that shock processes give rise to the filaments, because those forces release silicon monoxide (SiO), which is a useful molecule for detecting shock waves. The force also pushes several complex organic molecules into the gas phase, stirring them until they form filaments. Then, the slim filaments dissipate, releasing their contents back into the CMZ. Finally, those recently liberated molecules freeze into dust grains.If such filaments exist widely throughout the Milky Way, and the researchers theory is correct, their formation and dissolution represents a cyclical balance of depletion and replenishment of molecules in the galaxy.Article SourcesOur writers at Discovermagazine.com use peer-reviewed studies and high-quality sources for our articles, and our editors review for scientific accuracy and editorial standards. Review the sources used below for this article:Astronomy & Astrophysics. Astronomers Discover Space Tornadoes Around the Milky Ways CoreBefore joining Discover Magazine, Paul Smaglik spent over 20 years as a science journalist, specializing in U.S. life science policy and global scientific career issues. He began his career in newspapers, but switched to scientific magazines. His work has appeared in publications including Science News, Science, Nature, and Scientific American.

If youve walked past the penguin exhibit at the zoo, then youve likely caught a whiff of their unpleasant-smelling poo. The smell has perhaps made you want to cover your nose and, despite a penguins cuteness, want to walk away.Humans arent the only ones repelled by penguin poo, however. To krill, tiny shrimp-like creatures, the smell of penguin poo triggers evasive maneuvers, probably because they know that penguins are on their way to eat them. After putting it to the test, a research team has determined that a chemical within the poo causes krill to act erratically, according to a recent study published in Frontiers in Marine Science.Krill and their Scent TriggersAdlie penguins (Pygoscelis adeliae)(Image Credit: Nicole Hellessey)Krill are a keystone species in Antarctica and, unfortunately for them, they reside near the bottom of the food chain. They provide food for some marine species and one of those species is the Adlie penguin. According to the study, these penguins consume 1.6 kg (about 3.5 pounds) of krill per day, and theAdlie penguin population as a whole consumes about 1.5 trillion tons of krill annually.Krill are sensitive to chemicals in their environment. They rely on these triggers to find food and mates but also to adapt to environmental stressors like pollution and now, according to the new study, predators. According to the research team, a chemical in the Adlie penguins poo can trigger krill into evasive maneuvers.A Krill ExperimentFor the study, the research team collected krill from the Southern Ocean and brought them to a lab. There, the krill were kept in tanks and fed an algal slurry. During the experiment, the team placed six to eight krill together in a flume of seawater and manipulated the light and temperature so that it was the same as in the wild.From there, researchers then fed three types of water through the flume to mimic the oceans constant movement. Each of the three types of water contained either algae, penguin poo, or a mixture of both. After testing each group four times, the team found that krill reacted strongly to the scent of the penguin poo.Here we show for the first time that a small amount of penguin guano causes a sudden change in the feeding and swimming behaviors of Antarctic krill, said Nicole Hellessey, a postdoctoral researcher at the Bigelow Laboratory for Ocean Sciences in Maine, and the corresponding author of the study, in a press release.While krill typically swim in a head-on, straight line, after scenting the poo, they began to swim faster and made more frequent turns.Read More: How Do Penguin Wings Reach High Speeds Underwater?A Chemical ReactionBesides their change of speed and direction, the team also noticed that the krill displayed different feeding patterns after being exposed to the poo. According to the study, the krill reduced their consumption of algae by 64 percent when the poo was in the water, probably due to their frequent irregular, zig-zag movements.Such behavior to escape from nearby penguins would greatly increase the krills odds of survival. And these odds would increase exponentially in a swarm if their neighbors could detect the same cues and communicate the danger to each other, said Hellessey in a press release.However, what remains a mystery is which specific chemical in the poo causes this reaction? The research team has yet to determine it.We don't yet know how the ability of krill to sense these chemical cues and their escape behavior towards them might vary when diluted in open waters, or under global warming or ocean acidification conditions, Hellessey said in a press release. Any changes to krills behavior could have major impacts on the future Southern Ocean, as Antarctic krill are a keystone species in this ecosystem.Article SourcesOur writers at Discovermagazine.com use peer-reviewed studies and high-quality sources for our articles, and our editors review for scientific accuracy and editorial standards. Review the sources used below for this article:A graduate of UW-Whitewater, Monica Cull wrote for several organizations, including one that focused on bees and the natural world, before coming to Discover Magazine. Her current work also appears on her travel blog and Common State Magazine. Her love of science came from watching PBS shows as a kid with her mom and spending too much time binging Doctor Who.

HMS Tuberose aka RMS Mauretania enters New York harbour in full dazzle, carrying returning troops after the end of the Great War. Dated 1918.Credit: Photo12/Universal Images Group via Getty Images During World War I, Allied navies started implementing shocking, cubist-inspired dazzle paint jobs on ships. The now-iconic geometric designs were intended to throw off the visual perception of German U-boats crews and prevent them from accurately targeting ships with torpedoes. Conventional wisdom claims the bizarre camouflage pattern worked and helped turn the tide of Great War naval battles. But new research reevaluating one of the only rigorous studies testing that hypothesis suggests those conclusions were probably overblown. Researchers now claim another phenomena known as the horizon effect may have actually done more to throw off submarine gunners than the wacky aesthetic.The study, published last week by Aston University researchers in the journal i-Perception, recreated one of the few solid quantitative studies on dazzle ship effectiveness, updating the methods to meet modern scientific standards. The revised findings claim the original study substantially overestimated the effectiveness of dazzle camouflage. While the modernist designs may have played some role in distorting perceptions of a ships movement and direction, the new study found similar effects also occurred with ships painted in standard, single-color palettes. According to the researchers, U-boat gunners viewing ships from a distance likely fell for an optical illusion that made the vessels appear as if they were traveling along the horizon. That illusion likely occurred whether the ships were dazzled or not.These reappraised findings resolve an apparent conflict with the second quantitative experiment on dazzle ships conducted over a century later using computer displays online researchers write.Dazzle: A different kind of camouflageThe dazzle paint scheme originated around 1917 as a direct response to unyielding German U-boat attacks. German ships famously adopted an unrestricted submarine war policy at the start of the year which reportedly resulted in hundreds of sunken ships, both military and merchant, in less than one year. One of those downed boats, a British hospital vessel called the HMHS Lanfranc reportedly resulted in 40 deaths. Looking for a solution, English artist Norman Wilkinson approached Britains King George V with models of ships adorned in zig-zag and checkered patterns in shades of gray, black, white, green, orange, and blue. Wilkinson claimed these odd shapes, when viewed from a distance through a U-boat periscope, would distort the ships appearance just enough to make it difficult for submarine operators to accurately track and target them with torpedoes. Convinced by the demonstration, King George approved the implementation of dazzle designs across the British fleet.HMT Olympic in dazzle camouflage after service as a troopship during World War I, 1919.Credit: Pictures from History/Universal Images Group via Getty Images Pictures from HistoryWilkinsons dazzle approach followed on the heels of other, less practical proposals. Shipmakers had reportedly tried at various times to cloak vessels in mirrors and paint them to resemble giant clouds and whales. American inventor Thomas Edison even reportedly pushed forward an idea to reconfigure ships to look like floating islands lush with foliage. All of these ideas ultimately failed because they couldnt account for the constantly changing environments and weather conditions at sea. It simply wasnt possible to fully camouflage a ship in a way that consistently blended it into its surroundings. Dazzle took an entirely different approach. Rather than trying to disappear, the unorthodox geometric shapes aimed to confuse an observers perception of a ships movement and orientation from a distance.Did Dazzle actually work? New research casts doubt.Though widely adopted by both British and American vessels during the war, dazzle camouflage was mostly implemented based on assumption rather than solid evidence. Limited, high quality empirical research from the time actually measured whether or not the dazzle worked as advertised. One of the only remaining quantitative studies on its effectiveness was conducted in 1919 by an MIT naval architecture and marine engineering student named Leo Blodgett as part of his thesis.USS Leviathan in harbor, with tugs in attendance at her starboard bow, 1918. Credit: U.S. Naval History and Heritage Command Photograph. In the study, Blodgett painted model ships with dazzle patterns and placed them in a mock battle theater. He then observed them at a distance through a periscope and claimed the dazzle effect confused the observers perception of the ships movement. But when the Aston University researchers looked back over the findings they found several holes in the study, notably in Blodgetts control group, that didnt measure up to modern standards. Those shortfalls in the control experiment, according to researcher and co-author Samantha Strong, made Blodgetts experiment too vague to be useful. The Aston researchers went back in and created a new control experiment based on edited images of the original results. The newly improved methods showed the optical illusions occurring in cases where the ships did and did not have the dazzle paint.We ran our own version of the experiment using photographs from his thesis and compared the results across the original dazzle camouflage versions and versions with the camouflage edited out, Strong said. Our experiment worked well. Both types of ships produced the horizon effect, but the dazzle imposed an additional twist.If Blodgetts initial findings held true, the researchers noted, the front (or bow) of the ship would have consistently appeared to twist away from the direction it was actually traveling. In reality, the researchers found several instances where the observer perceived the ships bow twisting back around, even as it moved away. This illusion, they argue, likely had more to do with the horizon effecta phenomenon where a ship appears to travel along the horizon regardless of its actual directionthan with the dazzle camouflage itself. The researchers went on to note that ships traveling up to 25 degrees relative to a horizon will still look like they are traveling alongside it from the observers point of view.The remarkable finding here is that these same two effects, in similar proportions, are clearly evident in participants familiar with the art of camouflage deception, including a lieutenant in a European navy Aston University Professor and paper co-author Tim Meese said in a statement.Revealing as the findings are, they dont necessarily mean dazzle was completely ineffective. As noted in a 2016 Smithsonian report, merchant ships clad with the dazzle pattern during the war were reportedly granted lower insurance premiums. Some ship captains at the time also claimed crew morale appeared higher on ships with the dazzle pattern than those without. Even if the actual illusory effect of the dazzle was minimal, people bought into the hype and believed it was effective.In other words, never count out the placebo effect, even during times of war.

We finally made it to spring. Good bye winter, hello spring and all the storms that come with it. If you dont already have a portable power station or solar generator, now is the time to grab one. For one, youll get ahead of the possible power outages. And two, these Bluetti models are cheaper than they ever have been right now. If you use code POPSCI5OFF at checkout when buying the Elite 200 V2, you get an extra 5 percent off. BLUETTI Elite 200 V2 Portable Power Station $854 use coupon code POPSCI5OFF (was $1,699)BluettWeighing in at 53.4 pounds, this is a mighty little power station. It comes equipped with a 120W car port, four AC outlets, two 100W USB-C ports, and two USB-A ports. The 2073.6Wh battery holds enough juice to power the most energy-hungry devices, with up to 9 gadgets plugged in at once. This isnt an older lithium-ion battery, but rather a newer LiFePO cell thats good for up to 6,000 cycles and can fully recharge in under two hours. This thing can save you a real headache in an emergency or make camping a whole heck of a lot more fun. BLUETTI Handsfree 1 Solar Backpack Power Station, 268.8Wh 300W LiFePO4 Solar Generator $299 (was $429)BluettiSee ItThis unique solar generator setup fits into a full-on backpack that can also carry your gear. The IP-rated pack protects a 268Wh LiFePO battery pack inside that can supply juice to an entire campsite or keep devices charged over a long adventure. You can pack regular clothes, gadgets, and anything else in the main compartment along with the power supply. Plus, you can hang solar panels off the back of the pack to actually charge as you hike. More Bluetti portable power station and solar generator dealsBLUETTI AC2A Portable Power Station, 204Wh LiFePO4 Battery Backup $139 (was $219)BLUETTI EB3A Portable Power Station, 268Wh LiFePO4 Battery Backup $189 (was $269)BLUETTI X30 CPAP Battery Backup 297Wh Power Supply with Comprehensive Cable Set $250 (was $399)BLUETTI AC50B Portable Power Station, 448Wh LiFePO4 Battery Backup $279 (was $399)BLUETTI AC2A Portable Power Station with 100W Solar Panel Included $299 (was $499)BLUETTI EB3A Solar Generator with 100W Solar Panel Included $347 ($599)BLUETTI AC70 Portable Power Station, 768Wh LiFePO4 Battery Backup $359 (was $599)BLUETTI Handsfree 2 Solar Backpack Power Station $399 (was $599)BLUETTI AC180 Portable Power Station, 1152Wh LiFePO4 Battery Backup $449 (was $699)BLUETTI AC180 Solar Generator with 100W Solar Panel $679 (was $999)BLUETTI AC200L Portable Power Station, 2048Wh LiFePO4 Battery Backup $975 (was $1,599)BLUETTI AC200L Solar Generator with 200W Solar Panel $1,197 (was $1,899)BLUETTI AC300 Power Station with B300K Expansion Battery $1,499 (was $2,499)BLUETTI AC300 Power Station with B300K Expansion Battery with 2 200W Solar Panels $1,999 (was $3,199)The post Use this exclusive coupon code to get a Bluetti portable power station for its cheapest price ever appeared first on Popular Science.

Nature, Published online: 20 March 2025; doi:10.1038/s41586-025-08886-3Author Correction: Spatially resolved multiomics of human cardiac niches

Nature, Published online: 19 March 2025; doi:10.1038/s41586-025-08728-2Germinal centre Bcells modify their mutation rate to preserve high-affinity receptors, thereby safeguarding high-affinity Bcell lineages and enhancing the outcomes of antibody affinity maturation.

Fossilized vulture feathers that were stunningly preserved in volcanic ash were a mystery until now.

The Euclid space telescope has spotted 26 million galaxies in just one week of observations.

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.@saramolina3d joined us to discuss reimagining a Dishonored 1 environment in the style of Dishonored 2, adding her own creative twist using Unreal Engine 5, while also outlining her pipeline and plans for the project.Read: https://80.lv/articles/bringing-dishonored-environment-into-dishonored-2-s-world-with-unreal-engine-5/