The MINERvA experiment in the NuMI beam at Fermilab has made the first accurate image of the proton using neutrinos instead of light as the probe.
A novel experiment sheds new light on a possible mechanism that may seed magnetic fields for the galactic dynamo.
Ground-breaking image reconstruction and analysis algorithms filter out cosmic rays to pinpoint elusive neutrinos.
Scientists studied antimatter in the proton with higher precision than ever before, revealing insights into the particle’s puzzling dynamics.
Successful models of the fraught dynamics of two particle beams in close contact lead to smoother sailing in an area of particle acceleration.
The MicroBooNE experiment demonstrates the use of machine learning to interpret images made by a liquid-argon particle detector.
New crime scene investigation technique offers a hard look at the traces that particles leave before fleeing the scene.
Scientists developed a method to better distinguish the tracks that particles leave behind in liquid argon.
Scientists improve our understanding of the relationship between fundamental forces by re-creating the earliest moments of the universe.
Scientists are developing better models that describe both neutrino and antineutrino data, which can offer insights into the nature of the universe.
Neutral pion production is a major character in a story of mistaken identity worthy of an Agatha Christie novel.
MicroBooNE neutrino experiment cuts through the noise, clearing the way for signals made by the hard-to-detect particle.
