Space News & Blog Articles

Based on the most widely accepted models of how the Universe began - Big Bang cosmology and the LCDM model - scientists theorize that massive clouds of neutral hydrogen permeated the Universe. From this material, the first stars and galaxies formed rapidly over the next several hundred eons, an event that astronomers and cosmologists refer to as "Cosmic Dawn." For some time, it was further theorized that these early galaxies were surrounded by gigantic hydrogen gas halos, called "Lyman-alpha nebulae."

(This is Part 2 of a series on Cherenkov radiation — the "light boom." Read Part 1 first.)

Mars is well known as a static, frozen desert. We tend to think of the only thing changing on the surface of the Red Planet is due to the occasional dust storm. But if you look closely - and are willing to wait decades - you’ll see the planet is very much alive - at least in the environmental sense. The European Space Agency just released some spectacular new images from the High Resolution Stereo Camera (HRSC) on its Mars Express Orbiter, one of which shows a surprisingly “fast” geological change happening in Utopia Planitia. A dark, ominous-looking blanket of volcanic ash is actively creeping across the bright red sands - and it's moving (relatively) fast.

Comet R3 Pan-STARRS is about to put on its climatic perihelion act.

Two factors dominate our search for life and habitability elsewhere in the galaxy. The first is liquid water, which, as far as we know, is necessary for life. When we find exoplanets, scientists try to determine if they're in their stars' habitable zones. Under the right atmospheric conditions, liquid water could persist there.

Understanding the beginning of the solar system requires us to look at some very strange places. One such place is at the so-called “Trojan” asteroids that share Jupiter’s orbit in front of and behind it. But for a long time, these cosmic time capsules have held a mystery for astronomers: why are they color-coded? The populations of larger asteroids are very clear split into two distinct groups - the “reds” and the “less reds”, because apparently they’re all red to some extent. A new paper from researchers in Japan tried to solve this mystery by taking a close look at even smaller asteroids, and their findings, published in a recent edition of The Astronomical Journal, actually brings up a completely different question - why don’t smaller Trojan asteroids have the same color-coding?

In 2014, a strange cloudy object called G2 made a close approach to Sagittarius A*, (Sag A*) the supermassive black hole at the heart of the Milky Way Galaxy. Astronomers were pretty excited, partly because they thought it might get torn apart by Sag A*'s intense gravitational pull. That didn't happen, and the event turned out to be a cosmic fizzle. G2 skipped around the black hole, survived the flyby, and continued on a shortened orbit. Various observations showed that it wasn't just a gas cloud. It was likely a dusty protostellar object encased in a dusty cloud. Or perhaps several merged stars.

(This is Part 3 of a series on Cherenkov radiation — the "light boom." Read Part 1 and Part 2 first.)

Between the Artemis Program, the ESA's Moon Village, and the Sino-Russian International Lunar Research Station (ILRS), the next step in space exploration is clear: We're going back to the Moon, and this time, to stay! This plan requires significant investment, research, development, and strategies adapted to lunar conditions. In particular, mission planners are concerned about the hazard posed by lunar regolith (aka. "Moon dust"). In addition to being electrostatically charged, causing it to stick to literally any surface, it is incredibly fine and easily kicked up by rovers and spacecraft as they land and take off.

(This is the final part of a series on Cherenkov radiation — the "light boom." Read Part 1, Part 2, and Part 3 first.)

The Vera C. Rubin Observatory was built with an ambitious purpose in mind. As part of its 10-year Legacy Survey of Space and Time (LSST), the Rubin Observatory will gather about 30 petabytes of data. This will include creating an inventory of the Solar System, transient objects (such as supernovae and variable stars), and mapping the Milky Way. Using preliminary data gathered by the Observatory, scientists have already discovered 11,000 new asteroids in the Solar System. These results were confirmed by the International Astronomical Union's Minor Planet Center (IAU-MPC).

Living long-term on the Moon means surviving the devastating toll that deep space takes on a human body. Astronauts in low gravity environments suffer muscle and bone loss, vision-altering fluid shifts, and heavy radiation exposure - all of which are incredibly hazardous to our biology. So, to help future lunar explorers survive, a new crew just arrived at the International Space Station (ISS). That might not sound surprising, except this crew is composed of worms.

I want you to imagine a scene. It's the red carpet. It's the night of the Oscars, or the Emmys, or the participation trophy ceremony for your kid's soccer team. That's not the essential part of the metaphor. What matters is who is there: Brad Bradington's adoring fans, curious onlookers, and of course the paparazzi, ready to take their shot.

Venus is often called Earth's twin, but spend any time with it and the comparison falls apart quickly. Its surface is hot enough to melt lead, its atmosphere is a crushing blanket of carbon dioxide, and its clouds are made of concentrated sulphuric acid. Somewhere beneath those acid clouds, between the surface and the main cloud deck at around 47 kilometres up, a thin mysterious haze has drifted for billions of years, stubbornly resisting every attempt at explanation. Until now.

Reading the Mars Trilogy by Kim Stanley Robinson brings the benefits and pitfalls of efforts to terraform the Red Planet into sharp relief. Since the 1970s, when Carl Sagan first suggested the possibility that we could make Mars more Earth-like, that process has been a staple of science fiction. But there’s always been a significant amount of humanity that thinks we shouldn’t. A new paper available in pre-print on arXiv from Edwin Kite of the University of Chicago and his co-authors skirts around the ethical and moral questions of whether we should and tries to take a long hard look at whether we can.

Despite all we've learned about star formation, the process is still riven with mystery. Our prying telescopic eyes struggle to pierce the thick gaseous regions that give birth to stars. Progress has been steady, though, and we can thank the Atacama Large Millimeter/sub-millimeter Array (ALMA) for some of it.

NASA's Artemis II mission has completed its pass of the far side of the Moon, establishing a new distance record for a crewed spaceflight, over 400,000 km (250,000 mi) from Earth. And in the process, its four-person crew is capturing images of lunar regions no human has ever seen! Fortunately for the rest of us, they are beaming these images home and providing a treasure trove of scientific data in the process. The images, released on Tuesday, were captured by the crew on April 6th during their seven-hour flyby of the far side of the Moon.

Space is getting crowded - and not just with satellites, but with the massive amounts of data they’re generating. The amount of information being generated and passed through orbit is exploding. From high-resolution Earth observation images to global maritime monitoring, it’s also become a critical link in our infrastructure. But there’s another space this growing crowd of satellites is dependent on that is also filling up fast - the radio frequency spectrum. If we want to keep expanding our orbital infrastructure, we need to rethink how we move data around. On March 30, 2026, the European Space Agency (ESA) supported a series of eight CubeSats and one specialized payload on SpaceX’s Transporter-16 rideshare mission with the overarching goals of testing high-throughput laser communication, inter-satellite networking, and in-orbit artificial intelligence processing to make space data transfer faster, more secure, and vastly more efficient.

The nebular hypothesis states that stars and the planets that orbit them form from the same reservoir of material, called a solar nebula. It's the most commonly accepted explanation for how solar systems form. But despite its ability to explain many things about solar system formation, there are some outstanding questions.

Jupiter and Saturn, the two largest planets in the Solar System, are known for their large and varied systems of moons. At present count, Jupiter has more than 100 moons, while Saturn has more than double that, with over 280 known satellites. However, Jupiter's system of satellites includes four large moons - Io, Europa, Ganymede, and Callisto - and this system contains the largest moon in the Solar System (Ganymede). Meanwhile, Saturn's system of satellites is dominated by one large moon (Titan), the second largest in the Solar System.

Ten undergraduate students from the University of Chicago made an astounding discovery using data from the Sloan Digital Sky Survey (SDSS). As part of their "Field Course in Astrophysics," they located one of the oldest stars in the Universe living in the Milky Way. The star, SDSS J0715-7334, is a red giant with 29 times as much mass as our Sun, located 79,256 light-years away. But here's where things truly get interesting: according to their findings, this star wasn't born in the Milky Way, but migrated here from another galaxy. The team is led by Professor Alex Ji, the deputy Project Scientist for SDSS-V, and graduate teaching assistants Hillary Andales and Pierre Thibodeaux.