One year ago, our star erupted with almost apocalyptic force—unleashing the most violent solar assault in two decades. Dubbed the Gannon storm, it wasn't just another solar flare. Multiple coronal mass ejections collided and merged into a single devastating megastorm that slammed into Earth's protective shield. As our magnetosphere buckled the night skies exploded with spectacular auroral displays. The event even reached Mars with images from Curiosity sprinkled with streaks from charged particles.

Mars once flowed with water—then 3 billion years ago, it mysteriously disappeared. Where did these ancient Martian seas go? Did the Red Planet's collapsing magnetosphere allow solar winds to strip away its water into space or did the water sink into the Martian regolith, hiding from our view?NASA’s InSight mission may have cracked the case. Seismic waves from meteorite impacts revealed water layer lurking 5.4-8 kilometres below the surface.

ESA's Plato Mission just hit a major milestone: 24 of 26 high-tech cameras have now been mounted and will soon be ready to hunt. This isn't your average telescope; it’s a planet-spotting powerhouse designed to catch distant worlds passing in front of their stars. The clever camera arrangement creates a cosmic wide-angle lens, scanning a massive 5% of the entire sky in one go. No other planet-hunter comes close to this field of view.

NASA's Perseverance Rover landed in Jezero Crater, an ancient impact crater that was probably filled with water for a long time. During its exploration, the rover has discovered volcanic rocks on the crater floor, but the original source hasn't been found. Now, a team of researchers thinks there's a composite volcano right on the edge of Jezero Crater. They identify a conical-shaped structure that rises about 2 km above the surrounding plains.

Some parts of the Moon are more interesting than others, especially when searching for future places for humans to land and work. There are also some parts of the Moon that we know less about than others, such as the Irregular Mare Patches (IMPs) that dot the landscape. We know very little about how they were formed, and what that might mean for the history of the Moon itself. A new mission, called the LUnar Geology Orbiter (LUGO), aims to collect more data on the IMPs and search for lava tubes that might serve as future homes to humanity.

We don't have to rely solely on the JWST to observe the Universe's oldest stars. Some of the oldest stars in the Universe reside in globular clusters, and the Milky Way has about 150 of them. How old exactly? New research has the answer.

Extraordinary claims require extraordinary evidence. That truism, now known as the "Sagan standard" after science communication Carl Sagan, has been around in some form since David Hume first published it in the 1740s. But, with modern-day data collection, sometimes even extraordinary evidence isn't enough - it's how you interpret it. That's the argument behind a new pre-print paper by Luis Welbanks and their colleagues at Arizona State University and various other American institutions. They analyzed the data behind the recent claims of biosignature detection in the atmosphere of K2-18b and found that other non-biological interpretations could also explain the data.

Most astronomers agree that life is likely common throughout the Universe. While Earth is the only world known to have life, we know that life arose early on our world, and the building blocks of life, including amino acids and sugars, form readily. We also know there are countless worlds in the cosmos that might be home for life. But just because life is likely, that doesn't mean proving it will be easy. Many of the biosignatures we can observe can also have abiotic origins. So how can we be sure? One way is to compare our observations of a habitable world with other worlds in the system.

We tend to think of habitability in terms of individual planets and their potential to host life. But barring outliers like rogue planets with internal heating or icy moons with subsurface oceans created by tidal heating, it's exoplanet/star relationships that generate habitability, not individual planets. New research emphasizes that fact.

Over the past decade or so, astronomers have speculated about the characteristics of rogue planets in the Milky Way Galaxy. These "free-floating" worlds don't orbit stars, but instead roam the spaceways. They're hard to spot with current technology, but the upcoming Nancy Grace Roman Space Telescope (Roman) will be a perfect instrument to find them and give insights into the history and features they may have in common with Solar System worlds.