Around 2.2 billion years ago, a massive space rock collided against our planet, leaving a massive scar.
Around 200 million years older than any other site like it on the planet’s surface, the so-called Yarrabubba impact structure is located in Australia.
Although the impact site is the oldest found to date, finding it was not easy.
White holes, the theoretical opposites of black holes, could expel matter instead of absorbing it. Unlike black holes, whose event horizon traps everything, white holes would prevent anything from entering. While no white holes have been observed, they remain an intriguing mathematical possibility. Some astrophysicists have speculated that gamma ray bursts could be linked to white holes, and even the Big Bang might be explained by a massive white hole. Although the second law of thermodynamics presents a challenge, studying these singularities could revolutionize our understanding of space-time and cosmic evolution.
After reading the article, Harry gained more than 724 upvotes with this comment: “It amazes me how Einstein’s theory and equations branched off into so many other theoretical phenomena. Legend legacy.”
Black holes may well be the most intriguing enigmas in the Universe. Believed to be the collapsed remnants of dead stars, these objects are renowned for one characteristic in particular – anything that goes in never comes out.
Gaia BH3, a dormant black hole, quietly lurks 1,926 light-years away, nearly 33 times the Sun’s mass, making it one of the Milky Way’s largest stellar black holes.
Astronomers recently made a groundbreaking discovery: a dormant black hole named Gaia BH3, residing about 1,926 light-years away in the Milky Way’s Aquila constellation. Known as a “sleeping giant,” Gaia BH3 is approximately 33 times the Sun’s mass, making it the largest stellar black hole known in our galaxy. This black hole is only the second nearest to Earth, with Gaia BH1 slightly closer at around 1,500 light-years away.
The find was unintentional. Researchers were sifting through data from the European Space Agency’s Gaia space telescope, anticipating an upcoming data release when they noticed an unusual wobbling motion in a nearby star. This disturbance revealed the presence of Gaia BH3, whose immense gravitational force was causing a nearby giant star to orbit around it. This wobble marked the third dormant black hole identified by Gaia, a significant milestone in astronomical research.
A scheme that moves electromagnetically trapped ions around a 2D array of sites could aid development of scaled-up ion-based quantum computing.
Arrays of ions held in electromagnetic traps could eventually become powerful quantum computers, but as the number of ions increases, linear arrays become impractical. Rearranging the ions to achieve interactions between any specific pair becomes challenging, but now researchers have demonstrated a 2D scheme that does it more efficiently [1]. Using this approach, the full range of quantum operations is feasible with relatively simple applied voltages, and the researchers believe that it should soon find use in practical ion-based devices.
In trapped-ion quantum processors, single ions represent quantum bits (qubits). One of the main advantages of this technology is that individual ions can be moved around, says Robert Delaney of Quantinuum, a quantum-computing company. If rearranging ions—known as sorting—can bring every ion close enough to every other ion to allow pairwise quantum entanglement, the system has what is called all-to-all connectivity.
Cratons are fascinating yet enigmatic geological formations. Known to be relatively stable portions of the Earth’s continental crust, cratons have remained largely unchanged for billions of years. Although cratons have survived many geological events, some are undergoing decratonization—a process characterized by their deformation and eventual destruction.
The fastest animal on land is the cheetah, capable of reaching top speeds of 104 kilometers per hour. In the water, the fastest animals are yellowfin tuna and wahoo, which can reach speeds of 75 and 77 km per hour respectively. In the air, the title of the fastest level flight (excluding diving) goes to the white-throated needletail swift, at more than 112 km per hour.
We use our lips to talk, eat, drink, and breathe; they signal our emotions, health, and aesthetic beauty. It takes a complex structure to perform so many roles, so lip problems can be hard to repair effectively. Basic research is essential to improving these treatments, but until now, models using lip cells—which perform differently to other skin cells—have not been available.
In a study published in Frontiers in Cell and Developmental Biology, scientists report the successful immortalization of donated lip cells, allowing for the development of clinically relevant lip models in the lab. This proof-of-concept, once expanded, could benefit thousands of patients.
“The lip is a very prominent feature of our face,” said Dr. Martin Degen of the University of Bern.
UC Davis researchers have identified new cell clusters in the amygdala that could hold keys to treating anxiety and depression.
Effective treatment for anxiety, depression, and other emotional disorders may rely on the amygdala—a part of the brain that regulates strong emotional responses, particularly fear. Until recently, understanding of this structure was limited. Now, researchers at the University of California, Davis, have identified distinct clusters of cells in the amygdala of humans and non-human primates, each with unique patterns of gene expression. This discovery could pave the way for more targeted treatments for conditions like anxiety, which impact tens of millions worldwide.
The findings were published on October 30 in the American Journal of Psychiatry.
Scientists are using laser-based tracking and gravity data to improve how we monitor both satellites and space debris. By blending these methods, they can now predict orbits more precisely and gather insights on Earth’s gravity and water masses.
How are the Earth’s gravitational field and the paths of satellites and space debris connected? Earth’s gravitational field shapes the orbits of satellites and debris, and shifts in these orbits can reveal changes in the gravitational field, which also offers insights into water mass distribution on Earth.
In the COVER project, researchers at TU Graz’s Institute of Geodesy have enhanced gravity field calculations by combining satellite gravity measurements with satellite laser ranging (SLR). This approach not only improves gravity field models but also refines tracking and predictions for objects in orbit. These advancements are now available in the Gravity Recovery Object-Oriented Programming System (GROOPS) software—an open-source tool the Institute provides on GitHub.
In space exploration, long-distance optical links now enable the transmission of images, videos, and data from space probes to Earth using light.
However, for these signals to travel the entire distance undisturbed, hypersensitive receivers and noise-free amplifiers are essential. Researchers at Chalmers University of Technology in Sweden have now developed a system featuring a silent amplifier and an ultra-sensitive receiver, opening up possibilities for faster and more reliable space communication.
Space communication systems are increasingly relying on optical laser beams instead of traditional radio waves, as light experiences less signal loss over vast distances. However, even light-based signals weaken as they travel, meaning that optical systems need highly sensitive receivers to detect these faint signals by the time they reach Earth. Researchers at Chalmers have developed an innovative approach to optical space communication that could unlock new opportunities—and discoveries—in space.
