A detector that was designed to probe dark matter has seen an elusive nuclear decay called two-neutrino double electron capture—with implications for nuclear and particle physics.
Chinese scientists have carved out a space in the heart of a mountain where a search for dark matter will soon begin. It's just the first taste of what they hope to do there: Create the world's largest, deepest underground laboratory.
On April 28, 1947 Stanford Linear Electron Accelerator Project Report No. 7 announced the realization of a dream 15 years in the making: the linear acceleration of electrons.
What opera and physics may have in common, more than anything else, is their tendency to make most people cringe or fall asleep. Can an avant-garde opera that compares self-exploration to the physics of multiple dimensions invigorate audiences?
Every so often, particle physics communicators from labs around the world gather to swap strategies for getting people interested in science. At the group's April meeting in Japan, the big hit was toilet paper.
For a growing number of so-called Nerdcore rappers, the message is that people need to support basic research and math and science education if they want to hand future generations a nation worth bragging about.
How do you make the invisible visible? Astrophysicists face this challenge daily. Unlike astronomers who view stars through telescopes, astrophysicists study cosmic particles that are too small or dark to see directly.
Some of Fermilab's mechanical technicians spend a lot of time underground. In the echoing tunnels of the Tevatron collider they fix things, crawling behind equipment to replace aging nuts and bolts and repair everything from vacuum pumps to multi-ton superconducting magnets.