Antimatter's foundational particles can now reportedly be better-understood thanks to a new study that cools down such particles faster for easier control and better property observance. Researchers ...

When you buy through links on our articles, Future and its syndication partners may earn a commission. Eight years ago, scientists with the Alpha Magnetic Spectrometer (AMS-02) collaboration detected ...

Scientists studying the tracks of particles streaming from six billion collisions of atomic nuclei at the Relativistic Heavy Ion Collider (RHIC) -- an 'atom smasher' that recreates the conditions of ...

Matter and antimatter should have completely wiped each other out eons ago, leaving the Universe a very empty place. Obviously that didn't happen. Experiments at the Large Hadron Collider (LHC) may ...

Our universe is filled with particles, such as electrons and protons, which make up all the stuff on our planet and beyond: animals, plants, people, planets, asteroids, stars, gas clouds, and galaxies ...

The world's most massive science experiment has done it again, detecting hints of the heaviest antimatter particle ever found ...

The newly found antiparticle, called antihyperhydrogen-4, could have a potential imbalance with its matter counterpart that may help scientists understand how our universe came to be. When you ...

A simple explanation of dark matter and antimatter, how they differ, how scientists study them, and why both are important to understanding the universe.

Physicists have created the heaviest clumps of antimatter particles ever seen. Known as antihyperhydrogen-4, this strange stuff could help us solve some of the most puzzling physics mysteries.

In the world of science fiction, warp drives or antigravity devices are often powered by antimatter, which in real-life physics are mysterious particles that have an opposite charge and spin compared ...

CERN physicists have shown that antimatter falls downward due to gravity, just like regular matter, according to a new paper published in the journal Nature. It’s not a particularly surprising ...

An artistic representation of antihyperhydrogen-4 — an antimatter hypernucleus made of an antiproton, two antineutrons, and an antilambda particle — created in a collision of two gold nuclei (left).