Scientists have succeeded in measuring an atom made of antimatter for the first time ever, marking a giant step toward finding out how universe is formed, livescience.com reported Wednesday.

According to scientists all particles of matter have antimatter partners with equal mass and opposite charge. When the two parts meet, they destroy each other and become pure energy.

However, measuring antimatter had been impossible since universe is made of matter.

It is thought that the universe contained equal parts of matter and antimatter just after the Big Bang, which is considered starting point of the universe 13.7 billion years ago. But most of the matter and antimatter destroyed each other early on and left behind a slight surplus of matter that became the stars and galaxies that exist today.

In a new discovery, physicists at Switzerland’s CERN laboratory were able to track down the faintest trace of an antihydrogen atom, the anti-matter equivalent of hydrogen.

Hydrogen is the simplest atom among elements, containing one proton and one electron. Antihydrogen is made up of one antiproton and one positron, the antimatter equivalent of an electron.

After trapping antihydrogen atoms for several minutes by using magnetic fields to keep them suspended in one spot, researchers beamed microwave light at an antihydrogen atom and flipped its spin.

Then, the magnetic orientation of the particle changed, allowing the antiatom to escape and hit the walls of its trap made of matter. As the matter and antimatter collided, both were annihilated leaving behind a detectable mark.

“Precision-wise, it doesn’t compete with (measurement of) matter…but it’s the only one that’s ever been done on antimatter,” said Jeffrey Hangst of Denmark’s Aarhus University, spokesman for the CERN laboratory’s ALPHA experiment

The next step may be applying a more detailed measuring method called spectroscopy. This uses electromagnetic radiation to excite atom’s positron a higher energy level. As the positron returns to its normal energy level, it emits this energy as light. Measurement of the frequencies absorbed and emitted would allow for more accurate observations.

The researchers say if they find small changes between matter and antimatter, they may be closer to solving one of the ultimate cosmic questions concerning what happened to antimatter after Big Bang and why the universe is made up only of its counterpart.

Physicists’ best guess about the difference between two particles is that they behave slightly differently, for example, by decaying at different rates.



From news reports