The particles appear as lines because those pointlike particles are moving through space and time. A common rule is that time advances from the bottom to the top of the diagram.

Understand how to identify amplitude and frequency of waves and features of transverse and longitudinal waves with this guide for KS3 physics students aged 11-14 from BBC Bitesize.

This is how particles under magnetic influence organize their electrons. Typical metals, they explain, have a linear relationship between their energy and the strength of their magnetic field ...

Diagram of the tunnels at the Large Hadron Collider and ... If we could ramp our electromagnets — the “bending” magnets that keep particles moving in a circle — up to arbitrarily ...

The particles in solids move only by vibrating about a fixed position. ... In a diagram of the particles in a liquid, make sure that they are mostly touching but randomly arranged.

A report in Nature, published on Nov. 26, 2024, described how two teams of researchers are competing to be the first to move antimatter, hoping to initially transport antiprotons across CERN as a ...

The usual picture of space and time, and particles moving around in them, is a construct. ... Examples of “Feynman diagrams” were included on a 2005 postage stamp honoring Feynman.

Strange particles that have mass when moving one direction but no mass when moving in another were first theorised more than a decade ago. Now, these mass-shifting particles have been glimpsed in ...

To understand how one electron influences another, using Feynman diagrams, you have to imagine that the electrons, as they move through space and evolve in time, exchange a photon, here labeled ...

These Particles Only Move in One Direction. Scientists Think They Could Revolutionize Computing. From microcircuits to quantum computers, semi-Dirac fermions could change it all.