Physicists captured the first images of individual atoms freely interacting in space. The pictures reveal correlations among the 'free-range' particles that until now were predicted but never directly ...

Free-range atoms, roaming around without restrictions, have been captured on camera for the first time – enabling physicists ...

MIT physicists have taken the first-ever direct images of individual atoms interacting freely in space. Their findings, ...

This new experiment zeroed in on bosons, particles that tend to cluster and act like waves — a property predicted over a ...

MIT physicists have captured the first images of individual atoms freely interacting in space— “free-range” particles never ...

MIT scientists have snapped the first-ever images of individual atoms interacting freely in space, making visible the elusive ...

This confirmed a long-standing prediction based on Louis de Broglie's theory that boson bunching is a direct result of their ability to share one quantum wave - a hypothesis known as the de Broglie ...

In this state, bosons behave collectively as one big wave, predicted nearly a century ago by physicist Louis de Broglie. Directly imaging this phenomenon showed bosons clearly bunched together.

This confirmed a long-standing prediction based on Louis de Broglie's theory that boson bunching is a direct result of their ability to share one quantum wave - a hypothesis known as the de ...

This wave-like character was first predicted by physicist Louis de Broglie. It is the “de Broglie wave” hypothesis that in part sparked the beginning of modern quantum mechanics.

In a groundbreaking discovery, physicists have for the first time observed individual free-range atoms interacting in free space, confirming a quantum mechanical theory proposed over a century ago.

Physicists have used a novel technique to observe individual atoms interacting in free space for the first time ever. The new technique confirms a century-old quantum mechanical theory.