Yale researchers have created a new tool that will enable researchers to better view how RNA molecules function in tissue space.
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Astrocyte-derived vesicles could link stress to intestinal inflammation
Inflammatory bowel diseases (IBDs), such as Crohn’s disease and ulcerative colitis, are chronic and autoimmune conditions characterized by the inflammation of the intestinal tract. This inflammation can cause nausea or vomiting, diarrhea, abdominal pain and cramping, fatigue, fever, and various other debilitating symptoms.
While the underpinnings of IBDs have been widely investigated, the factors that can contribute to its emergence have not yet been clearly elucidated. Past findings suggest that the symptoms of these diseases are often exacerbated by psychological and emotional stress.
Researchers at Universidad de los Andes and the Center of Interventional Medicine for Precision and Advanced Cellular Therapy (IMPACT) in Chile recently carried out a study aimed at shedding new light on the neurobiological mechanisms via which stress could worsen IBDs. Their findings, published in Molecular Psychiatry, hint at the existence of a brain-to-gut communication pathway that is mediated by small communication vehicles known as small extracellular vesicles (sEVs), which are released by astrocytes.
Using entanglement to test whether gravity is quantum just got more complicated
Unifying gravity and quantum theory remains a significant goal in modern physics. Despite the success in unifying all other fundamental interactions (electromagnetism, strong force and weak force) with quantum mechanics and many attempts at explaining a “quantum gravity,” scientists are still coming up short. Still, some believe we are getting closer to determining whether these two theories can be combined or whether they are truly incompatible.
A major contender for proving or disproving whether gravity is quantum is Richard Feynman’s proposed experiment to test if gravity can entangle two massive objects. In theory, such entanglement would indicate quantum behavior. While it was not actually feasible to do this experiment in 1957, when Feynman came up with the idea, new scientific advances are bringing it closer to reality.
However, a new study, published in Nature, claims that it’s a little more complicated than this. The researchers involved in the study determined, through their calculations, that entanglement is not necessarily evidence of quantum gravity—and that classical gravity can generate this entanglement in some cases too.
Google claims its latest quantum algorithm can outperform supercomputers on a real-world task
Researchers from Google Quantum AI report that their quantum processor, Willow, ran an algorithm for a quantum computer that solved a complex physics problem thousands of times faster than the world’s most powerful classical supercomputers. If verified, this would be one of the first demonstrations of practical quantum advantage, in which a quantum computer solves a real-world problem faster and more accurately than a classical computer.
In a new paper published in the journal Nature, the researchers provided details on how their algorithm, called Quantum Echoes, measured the complex behavior of particles in highly entangled quantum systems. These are systems in which multiple particles are linked so that they share the same fate even when physically separated. If you measure the property of one particle, you instantly know something about the others. This linkage makes the overall system so complex that it is difficult to model on ordinary computers.
The Quantum Echoes algorithm uses a concept called an Out-of-Time-Order Correlator (OTOC), which measures how quickly information spreads and scrambles in a quantum system. The researchers chose this specific measurement because, as they state in the paper, “OTOCs have quantum interference effects that endow them with a high sensitivity to details of the quantum dynamics and, for OTOC, also high levels of classical simulation complexity. As such, OTOCs are viable candidates for realizing practical quantum advantage.”
Record-breaking quantum key distribution transmission distance achieved alongside classical channels
Quantum key distribution (QKD) harnesses the power of quantum mechanics to securely transmit confidential information. When an outside source eavesdrops on a QKD transmission, the quantum states are affected. This dependably alerts the receiver and sender that the transmission is no longer secure.
Unfortunately, there have thus far been limitations in implementing QKD technology. Telecom networks require QKD and classical data to share fiber infrastructure to reduce costs enough to be feasible on a large scale and classical data channels introduce noise that limits the distance and performance of QKD transmissions. Many solutions have been proposed and tested, such as extra filtering or dedicated wavelengths, but these still complicate integration into existing telecom networks.
Now, researchers from Denmark and the Czech Republic may have a better solution that, when tested, broke the record for the longest transmission achieved with QKD and classical data.
Scientists discover elusive solar waves that could power the sun’s corona
Researchers have achieved a breakthrough in solar physics by providing the first direct evidence of small-scale torsional Alfvén waves in the sun’s corona—elusive magnetic waves that scientists have been searching for since the 1940s.
The discovery, published in Nature Astronomy, was made using unprecedented observations from the world’s most powerful solar telescope, the U.S. National Science Foundation (NSF) Daniel K. Inouye Solar Telescope in Hawaii.
The findings could finally explain one of the sun’s greatest mysteries—how its outer atmosphere, the corona, reaches temperatures of millions of degrees while its surface is only around 5,500°C.
Cosmic inflation with standard particle physics repertoire
How did the universe come into being? There are a multitude of theories on this subject. In a Physical Review Letters paper, three scientists formulate a new model: according to this, inflation, the first, very rapid expansion of the universe, would have taken place in a warm environment consisting of known elementary particles.
Isotropic MOF coating reduces side reactions to boost stability of solid-state Na batteries
In recent years, energy engineers have been trying to design new reliable batteries that can store more energy and allow electronics to operate for longer periods of time before they need to be charged. Some of the most promising among these newly developed batteries are solid-state batteries, which contain solid electrolytes instead of liquid ones.
Compared to batteries with liquid electrolytes that are widely used today, solid-state batteries could exhibit higher energy densities (i.e., could store more energy) and longer lifetimes. However, many of these batteries have been found to be unstable, due to unwanted chemical reactions that occur between their high-voltage cathodes (i.e., positive electrodes) and solid electrolytes, which can speed up the degradation of the batteries’ performance over time.
These undesirable side reactions are particularly common in sodium-ion (Na+) solid-state batteries, which use Na+ ions to store and release electrical energy. This is because while Na is more abundant and cheaper than lithium, Na-ion batteries are inherently more chemically reactive than Li-ion batteries.
Double-layer electrode design powers next-gen silicon-based batteries for faster charging and longer range EVs
New research, led by Queen Mary University of London, demonstrates that a double-layer electrode design, guided by fundamental science through operando imaging, shows remarkable improvements in the cyclic stability and fast-charging performance of automotive batteries, with strong potential to reduce costs by 20–30%.
The research, published today in Nature Nanotechnology, was led by Dr. Xuekun Lu, Senior Lecturer in Green Energy at Queen Mary University of London.
In the study, the researchers introduce an evidence-guided double-layer design for silicon-based composite electrodes to tackle key challenges in the Si-based electrode — a breakthrough with strong potential for next-generation high-performance batteries.