An international team, including astronomers from Keele University, has performed a unique cosmic test to measure the mass of an ancient star, which will help them learn more about the history of our galaxy.

IN A NUTSHELL 🌌 Astronomers discovered a massive filament of hot gas stretching 23 million light-years, containing much of the universe’s “missing matter.” 🔭 Advanced telescopes like XMM-Newton and Suzaku played a crucial role in identifying and analyzing this elusive cosmic structure. 🕸️ The filament is part of the Cosmic Web, a network that has
The discovery of more than 15,000 kilometers of ancient riverbeds on Mars suggests that the Red Planet may once have been much wetter than previously thought.
Researchers looked at fluvial sinuous ridges, also known as inverted channels, across Noachis Terra—a region in Mars’ southern highlands. These are believed to have formed when sediment deposited by rivers hardened and was later exposed as the surrounding material eroded.
Similar ridges have been found across a range of terrains on Mars. Their presence suggests that flowing water was once widespread in this region of Mars, with precipitation being the most likely source of this water.
SPHEREx is scanning the entire sky in 102 infrared colors, beaming weekly data to a public archive so scientists and citizen stargazers alike can trace water, organics, and the universe’s first moments while NASA’s open-science philosophy turbo-charges discovery. NASA’s newest space telescope, SPHE
Serendipitous discovery of djerfisherite in Ryugu grain challenges current paradigm of the nature of primitive asteroids. A surprising discovery from a tiny grain of asteroid Ryugu has rocked scientists’ understanding of how our Solar System evolved. Researchers found djerfisherite—a mineral typically born in scorching, chemically reduced conditions and never before seen in Ryugu-like meteorites—inside a sample returned by Japan’s Hayabusa2 mission. Its presence suggests either Ryugu once experienced unexpectedly high temperatures or that exotic materials from other parts of the solar system somehow made their way into its formation. Like discovering a palm tree fossil in Arctic ice, this rare find challenges everything we thought we knew about primitive asteroids and the early mixing of planetary ingredients.
The pristine samples from asteroid Ryugu returned by the Hayabusa2 mission on December 6, 2020, have been vital to improving our understanding of primitive asteroids and the formation of the Solar System. The C-type asteroid Ryugu is composed of rocks similar to meteorites called CI chondrites, which contain relatively high amounts of carbon, and have undergone extensive aqueous alteration in their past.
A research team at Hiroshima University discovered the presence of the mineral djerfisherite, a potassium-containing iron-nickel sulfide, in a Ryugu grain. The presence of this mineral is wholly unexpected, as djerfisherite does not form under the conditions Ryugu is believed to have been exposed to over its existence. The findings were published on May 28, 2025, in the journal Meteoritics & Planetary Science.
New research utilizing data from NASA’s Parker Solar Probe has provided the first direct evidence of a phenomenon known as the “helicity barrier” in the solar wind. This discovery, published in Physical Review X by Queen Mary University of London researchers, offers a significant step toward understanding two long-standing mysteries: how the sun’s atmosphere is heated to millions of degrees and how the supersonic solar wind is generated.
The solar atmosphere, or corona, is far hotter than the sun’s surface, a paradox that has puzzled scientists for decades. Furthermore, the constant outflow of plasma and magnetic fields from the sun, known as the solar wind, is accelerated to incredible speeds.
Turbulent dissipation —the process by which mechanical energy is converted into heat—is believed to play a crucial role in both these phenomena. However, in the near-sun environment, where plasma is largely collisionless, the exact mechanisms of this dissipation have remained elusive.
Long overlooked and underestimated, glial cells—non-neuronal cells that support, protect and communicate with neurons—are finally stepping into the neuroscience spotlight. A new Florida Atlantic University study highlights the surprising influence of a particular glial cell, revealing that it plays a much more active and dynamic role in brain function than previously thought.
Using sophisticated computational modeling and machine learning, researchers discovered how astrocytes, a “star” shaped glial cell, subtly—but significantly—modulate communication between neurons, especially during highly coordinated, synchronous brain activity.
“Clearly, glial cells are significantly implicated in several brain functions, making identifying their presence among neurons an appealing and important problem,” said Rodrigo Pena, Ph.D., senior author, an assistant professor of biological sciences within FAU’s Charles E. Schmidt College of Science on the John D. MacArthur Campus in Jupiter, and a member of the FAU Stiles-Nicholson Brain Institute.
Water frozen in the darkness of space doesn’t appear to behave the way we thought.
A new research effort using computer simulations and experiments to explore the most common form water takes in the Universe has found that it is not as structureless as scientists had thought. Rather, repeating patterns – otherwise known as crystals – just a few nanometers across are likely embedded in an otherwise frozen jumble of molecules.
Since scientists had thought space too cold for ice crystals to have the energy to form, this discovery comes as a big surprise.
A small, inconspicuous meteorite may be about to change our understanding of how and when our solar system formed. Tiny shavings from the meteorite Northwest Africa 12264 are challenging the long-held belief that planets near the sun formed earlier than those beyond the asteroid belt, between Mars and Jupiter.