“The level of control the authors have achieved over an individual antimatter particle is unprecedented,” says Dmitry Budker, ...

Physicists have discovered that when beams of light interact at the quantum level, they can generate ghost-like particles ...

It won’t make its way into quantum computers, but it could help us understand why the universe is filled with matter.

According to the Standard Model (SM) of particle physics, the building blocks of the universe are quantum fields defined by ...

The magnetic moment of the muon—a tiny property of a tiny particle—has long puzzled physicists. Experiments and theory haven’t quite matched up, leaving open the thrilling possibility of discovering ...

Imagine two flashlights aimed at each other; do their beams collide? Nope! In everyday physics, light is too chill for drama.

Instead of the big bang, some physicists have suggested that our universe may have come from a big bounce following another ...

In a breakthrough for antimatter research, the BASE collaboration at CERN has kept an antiproton – the antimatter counterpart ...

But the quantum world is not simple, and the moment is slightly different from 2. This is the anomalous magnetic moment, and it is often represented by the expression of g-2 (gee minus two).

In addition to the astroparticle physics that makes up the bulk of SNOLAB’s scientific program, the unique environment in the lab also facilitates research in biology, geology and quantum computing.