For the first time, scientists have measured the rate at which high-energy neutrinos are absorbed by our planet, a development that could lead to discoveries about physics and the Earth.
Mesons. Bosons. Pions. Muons. Asparagus. Yes, asparagus. Physicists have spare time, too, and a few of them spend it in Fermilab's Garden Club, with roots almost as old as the lab itself.
The sighting of Jupiter's moons by Galileo Galilei resonates through science and history. Using a handmade telescope in January 1610, Galileo confirmed the Copernican theory that the planets moved around the sun; the Earth was not the center of the solar system.
Street banners honoring nine of Berkeley Lab's Nobel Prize winners, originally installed along Telegraph Avenue in 2003, have been mounted on poles on Cyclotron Road leading to Berkeley Lab in honor of its 75th anniversary.
The neutrino experiment K2K (KEK to Kamioka) collaboration shares a logbook with Super-Kamiokande scientists at its far detector site 250 kilometers from KEK in Tsukuba.
Forty years ago, Korea was a poor country with low per capita income, considered a developing nation by the rest of the world. Things have changed–enormously. Today, Korea is an industrial powerhouse; its 50 million citizens are recognized for the production of cars and electronic goods.
You can't start a high-energy physics program in a remote third-world country overnight. But you might be able to do it in fifteen years. That is what Vietnamese and American physicists hope to do by helping Vietnamese students to become part of the worldwide particle physics community.
Pakistan does not have a long history of domestic particle physics experiments, but the country is nevertheless finding ways to contribute to international efforts.