CERNが反物質の陸上輸送に初めて成功

CERN researchers are set to transport around 100 antiprotons by truck around the campus near Geneva, Switzerland, on Tuesday. This marks the first demonstration of a planned antimatter delivery service to labs across Europe. The experiment, known as STEP, aims to enable precision measurements away from the noisy antimatter factory.

2026年04月19日(日) AIによるレポート

CERN's BASE experiment has begun more precise antiproton studies thanks to the recent first-ever truck transport of antimatter around the France-Switzerland site. Spokesperson Stefan Ulmer says moving 92 antiprotons away from production magnets is key to probing why the universe has more matter than antimatter.

Physicists at MIT have developed a theoretical technique inspired by the film Interstellar to send messages backwards in time using quantum entanglement. The approach mimics closed time-like curves and surprisingly improves communication through noisy channels. While actual time travel remains impossible, the idea could enhance conventional systems.

2026年03月18日(水) AIによるレポート

Physicists on the LHCb experiment at CERN's Large Hadron Collider have detected the Xicc+ particle, a baryon containing two charm quarks and one down quark. This heavier analogue of the proton resolves a 20-year-old mystery from a previous experiment. The discovery, confirmed at over 7 sigma significance, highlights upgrades to the LHCb detector.

Two precise experiments have agreed on a proton radius of about 0.84 femtometres, aligning with a surprising 2010 measurement and resolving a long-standing puzzle in particle physics. Researchers used lasers to study electron transitions in hydrogen atoms. The findings, published in Nature and Physical Review Letters, boost confidence in the smaller proton size.

2026年04月26日(日) AIによるレポート

An international team of researchers has detected signs of a rare η′-mesic nucleus, a fleeting particle trapped inside an atomic nucleus. This exotic state, observed in a high-precision experiment, suggests the η′ meson's mass decreases in dense nuclear matter. The finding could shed light on how matter acquires mass through the structure of space's vacuum.