Physicists devise an idea for lasers that shoot beams of neutrinos
Super-cooling radioactive atoms could produce a laser-like neutrino beam, offering a new way to study these ghostly particles — and possibly a new form of communication.
Super-cooling radioactive atoms could produce a laser-like neutrino beam, offering a new way to study these ghostly particles — and possibly a new form of communication.
Researchers with the KATRIN experiment determine that neutrinos are lighter than 0.8 eV/c2.
A National Science Foundation-funded team will use artificial intelligence to speed up discoveries in physics, astronomy, and neuroscience.
Graduate student Nicholas Kamp describes the MicroBooNE experiment and its implications for our understanding of fundamental particles.
Senior Anjali Nambrath will graduate with majors in physics and mathematics, a minor in French — and a deep love for theater.
Joseph Formaggio explains the discovery that the ghostly particle must be no more than 1 electronvolt, half as massive as previously thought.
Most thorough test to date finds no Lorentz violation in high-energy neutrinos.
The “ghostly particle” is confirmed to have originated from a blazar, nearly 4 billion light years from Earth.
Data could shed light on why the universe has more matter than antimatter.
Pocket-sized device detects charged particles in surrounding air.
Exotic metal displays behavior that could lead to new infrared detectors.
If discovered, sterile neutrinos may explain dark matter.
Neutrinos traveling 450 miles have no individual identities, according to MIT analysis.
Physicist Joseph Formaggio discusses the significance of this year’s Nobel Prize in physics, MIT’s involvement in neutrino research.