An anonymous reader quotes a report from NewAtlas: After an almost two-year shutdown for repairs and upgrades, CERN's Large Hadron Collider (LHC) is beginning to fire back up for its next phase of probing the mysteries of physics. Its newest particle accelerator, Linac 4, completed its first test run over the past few weeks, with the potential to provide much more energetic beams than ever before. The LHC paused operations in December 2018, beginning a massive overhaul called the High-Luminosity Large Hadron Collider (HL-LHC). When it's fully finished and finally fired up in 2026, the upgraded facility will be seven times more powerful and will collect around 10 times more data in the following decade than it did during the previous run. And now, the first incremental stage of this upgrade is coming online. The new linear accelerator, called Linac 4, has been installed and tested over the last few weeks. This device is the starting point for accelerating protons, which are then injected into the Proton Synchrotron (PS) Booster and onto the rest of the accelerator complex. Linac 4 replaces Linac 2, which was in operation at CERN for 40 years. As you might expect the new model is significantly more powerful, injecting particles into the PS Booster at energies up to 160 MeV -- much higher than Linac 2's 50 MeV. By the time these beams are boosted, they'll reach energies of 2 GeV, compared to the 1.4 GeV that Linac 2 was capable of. This extra energy is thanks to the fact that scientists can tweak Linac 4's beams in much more detail than its predecessor. In the three weeks up to mid-August, Linac 4 was tested with low-energy beams of negative hydrogen ions, running only through the first part of the accelerator. On August 20, it was finally cranked right up to maximum energy, with beams accelerated through the whole machine. These were then sent into a "beam dump" at the end, a device that catches and absorbs the particles.

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Back in 2012, a team of Japanese and Belgian researchers in Antarctica found a golf ball-sized space rock resting in the snow. Now, NASA astronauts have had a chance to study a piece of that meteorite, Asuka 12236, and they say it may hold new clues about the development of life. From a report: Inside the meteorite, astrobiologists from NASA's Goddard Space Flight Center found a high concentration of amino acids, particularly aspartic and glutamic acids. Those are two of the 20 amino acids that make millions of proteins, which are essential for the bodily functions of animals. Researchers have found amino acids in other space rocks, but not at such a high concentration. Perhaps most surprisingly, Asuka 12236 contains more left-handed versions of some amino acids. While there are right-handed and left-handed versions of each amino acid, life as we know it uses only left-handed amino acids to build proteins. Researchers want to know why there was an imbalance toward left-handed amino acids and what kinds of space conditions might have led to that. They believe Asuka 12236 was exposed to very little heat or water -- two important clues.

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New submitter HotSyncer shares a report from Phys.Org: [I]n a paper published on Aug. 17, in Nature Nanotechnology, Stanford scientists demonstrate a new approach to slow light significantly, much like an echo chamber holds onto sound, and to direct it at will. Researchers in the lab of Jennifer Dionne, associate professor of materials science and engineering at Stanford, structured ultrathin silicon chips into nanoscale bars to resonantly trap light and then release or redirect it later. These "high-quality-factor" or "high-Q" resonators could lead to novel ways of manipulating and using light, including new applications for quantum computing, virtual reality and augmented reality; light-based WiFi; and even the detection of viruses like SARS-CoV-2. "We're essentially trying to trap light in a tiny box that still allows the light to come and go from many different directions," said postdoctoral fellow Mark Lawrence, who is also lead author of the paper. "It's easy to trap light in a box with many sides, but not so easy if the sides are transparent -- as is the case with many Silicon-based applications."

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sciencehabit shares a report from Science Magazine: Nearly 60 years ago, the Nobel prize-winning physicist Eugene Wigner captured one of the many oddities of quantum mechanics in a thought experiment. He imagined a friend of his, sealed in a lab, measuring a particle such as an atom while Wigner stood outside. Quantum mechanics famously allows particles to occupy many locations at once -- a so-called superposition -- but the friend's observation "collapses" the particle to just one spot. Yet for Wigner, the superposition remains: The collapse occurs only when he makes a measurement sometime later. Worse, Wigner also sees the friend in a superposition. Their experiences directly conflict. Now, researchers in Australia and Taiwan offer perhaps the sharpest demonstration that Wigner's paradox is real. In a study published this week in Nature Physics, they transform the thought experiment into a mathematical theorem that confirms the irreconcilable contradiction at the heart of the scenario. The team also tests the theorem with an experiment, using photons as proxies for the humans. Whereas Wigner believed resolving the paradox requires quantum mechanics to break down for large systems such as human observers, some of the new study's authors believe something just as fundamental is on thin ice: objectivity. It could mean there is no such thing as an absolute fact, one that is as true for me as it is for you.

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Time magazine reports on is a big scientific advance: "the understanding that our bodies often operate according to different clocks." Although the federal government recommends that Americans sleep seven or more hours per night for optimal health and functioning, new research is challenging the assumption that sleep is a one-size-fits-all phenomenon. Scientists have found that our internal body clocks vary so greatly that they could form the next frontiers of personalized medicine... Human sleep is largely a mystery. We know it's important; getting too little is linked to heightened risk for metabolic disorders, Type 2 diabetes, psychiatric disorders, autoimmune disease, neurodegeneration and many types of cancer. "It's probably true that bad sleep leads to increased risks of virtually every disorder," says Dr. Louis Ptacek, a neurology professor at the University of California, San Francisco... The ideal sleep duration has long been thought to be universal. "There are many people who think everyone needs eight to eight and a half hours of sleep per night and there will be health consequences if they don't get it," says Ptacek. "But that's as crazy as saying everybody has to be 5 ft. 10 in. tall. It's just not true..." About a decade ago, Ptacek's wife Ying-Hui Fu discovered the first human gene linked to natural short sleep; people who had a rare genetic mutation seemed to get the same benefits from six hours of sleep a night as those without the mutation got from eight hours. In 2019, Fu and Ptacek discovered two more genes connected to natural short sleep, and they'll soon submit a paper describing a fourth, providing even more evidence that functioning well on less sleep is a genetic trait... Doctors once dismissed short sleepers as depressed or suffering from insomnia. Yet short sleepers may actually have an edge over everyone else. Research is still early, but Fu has found that besides being more efficient at sleep, they tend to be more energetic and optimistic and have a higher tolerance for pain than people who need to spend more time in bed. They also tend to live longer.

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Squid are among the smartest ocean dwellers. Along with other ink-squirting cephalopods like octopuses and cuttlefish, squid boast the largest brains of all invertebrates. They also have an incredibly complex nervous system capable of instantaneously camouflaging their bodies and communicating with each other using various signals. From a report: Scientists have long marveled at these sophisticated behaviors and have tried to understand why these tentacled creatures are so intelligent. Gene editing may be able to help researchers unravel the mysteries of the cephalopod brain. But until now, it's been too hard to do -- in part because cephalopod embryos are protected by a hard outer layer that makes manipulating them difficult. Recently, a group of marine scientists managed to engineer the first genetically altered squid using the DNA editing tool CRISPR. In addition to being a big milestone in biology, the advance has potential implications for human health: Because of their big brains, cephalopods are used to study neurodegenerative diseases like Alzheimer's and Parkinson's. The ability to edit the genes of these animals could help scientists study the genes involved in learning and memory as well as specific cephalopod behaviors. "I think you're going to see a huge jump in the use of these [gene-edited] organisms by neurobiologists," Joshua Rosenthal, PhD, a senior scientist at the Marine Biological Laboratory in Woods Hole, Massachusetts, and a key architect of the first genetically engineered squid, tells OneZero. Rosenthal and his colleagues used CRISPR to snip out a gene responsible for the coloring of the squid's skin. As a result, the edited squid were transparent instead of having their usual reddish spots. The results were published July 30 in the journal Current Biology. But why bother to create a colorless squid? Rosenthal says the pigmentation gene was a logical starting place for experimentation. "If you see the pigmentation go away, it's easy to see if the gene editing is working," he explains. Being able to tinker with cephalopod DNA will allow scientists to better study what their individual genes do at a very basic level. The accomplishment wasn't easy. Scientists have successfully made gene-edited mice, monkeys, and other research animals to help them study a range of behaviors and medical conditions. But until now, they hadn't been successful at manipulating the genes of cephalopods.

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