A new study has proposed that the detection of antihelium in cosmic rays could be evidence of a new category of particles ...

The discovery could help scientists get closer to understanding the mysterious invisible matter that makes up the bulk of our ...

Join six leading experts to find out everything we know about the subatomic universe. Take a deep dive into the building ...

Scientists are working on an ambitious dark matter experiment in space in the hope it can unravel one of the universe's ...

There's a significant imbalance between matter and antimatter in our universe ... of "ghost particles" may be responsible for all the dark matter in the universe — and the reason that there ...

The majority of our evidence for dark matter’s existence comes from observing visible (or baryonic) matter that does not ...

why there is more matter than antimatter, and why the universe is filled with dark matter. This is all hypothetical, but definitely worth pursuing. And if we ever discover evidence for right ...

Because we haven't found anything yet, we've started to wonder if dark matter might be lighter or heavier than we thought.

The presence of these particles, especially from the decay of WIMPs (Weakly Interacting Massive Particles), could point toward dark matter interactions. If this breakthrough holds, it may reshape ...

Dark matter could be baryonic (made of protons, neutrons, and electrons) or non-baryonic (composed of different types of particles). Most scientists believe it is non-baryonic. Antimatter ...

Antimatter, in simple terms ... produce antihelium nuclei and offer a tantalising clue to the nature of dark matter. The hunt for dark matter has been one of the greatest challenges in modern ...