In this video, we explore the fundamental forces of nature and their interactions with particles, structured as follows: 0:00 ...

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Two experiments with different quantum computers showcase their growing ability to simulate materials and quantum matter that have so far proven elusive in the lab ...

A report from the ATLAS experiment. Fig. 1. Combined Run 2 and Run 3 results for weighted dimuon (top) and Zγ (above) invariant mass spectra, summed over all event categories. The data are compared to ...

The world around us is made of two fundamentally different kinds of particles: fermions and bosons. Fermions are solitary by nature — if they were cars on a busy road, each one would be forced to ...

"Hearst Magazines and Yahoo may earn commission or revenue on some items through these links." Until now, atoms have never been imaged interacting freely in space, but a new technique known as ...

MIT physicists have taken the first-ever direct images of individual atoms interacting freely in space. Their findings, published in the journal Physical Review Letters, reveal hidden quantum ...

Using single-atom-resolved microscopy, ultracold quantum gases composed of two types of atoms reveal distinctly different spatial correlations — the bosons on the left exhibit bunching, while the ...

The images were taken using a technique developed by the team that first allows a cloud of atoms to move and interact freely. The researchers then turn on a lattice of light that briefly freezes the ...

Scientists from the Massachusetts Institute of Technology (MIT) in the U.S. have made a groundbreaking achievement after they captured the first images of individual atoms freely interacting in space.