Neutrinos

A neutrino is represented as a sphere with the letter ‘v,’ and is shot out through space like a laser.

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.

September 8, 2025

The interior of the KATRIN main spectrometer, a shiny silver, mainly spherical structure, with the field shaping wire electrodes in view.

A new upper limit on the mass of neutrinos

Researchers with the KATRIN experiment determine that neutrinos are lighter than 0.8 eV/c2.

February 14, 2022

A photo of three men standing outside, at the top of a staircase and in front of an intricately carved set of wooden doors

Taming the data deluge

A National Science Foundation-funded team will use artificial intelligence to speed up discoveries in physics, astronomy, and neuroscience.

October 29, 2021

A blue image with a greenish line going from roughly bottom left to top right, with a number of dots and smudges, also greenish, toward the top-right quadrant of the image.

3 Questions: Investigating a long-standing neutrino mystery

Graduate student Nicholas Kamp describes the MicroBooNE experiment and its implications for our understanding of fundamental particles.

October 28, 2021

Photo of Anjali Nambrath, smiling and outdoors with an athletic field in the background

Ways of seeing the world

Senior Anjali Nambrath will graduate with majors in physics and mathematics, a minor in French — and a deep love for theater.

May 4, 2021

KATRIN’s spectrometer, shown here, precisely measures the energy of electrons emitted in the decay of tritium, which has helped scientists come closer to pinning down the mass of the ghost-like neutrino.

3Q: Scientists shave estimate of neutrino’s mass in half

Joseph Formaggio explains the discovery that the ghostly particle must be no more than 1 electronvolt, half as massive as previously thought.

September 16, 2019

New study again proves Einstein right

Most thorough test to date finds no Lorentz violation in high-energy neutrinos.

July 16, 2018

In this illustration, a neutrino has interacted with a molecule of ice, producing a secondary particle—a muon—that moves at relativistic speed in the ice, leaving a trace of blue light behind it.

3Q: Janet Conrad on the first detection of a neutrino’s cosmic source

The “ghostly particle” is confirmed to have originated from a blazar, nearly 4 billion light years from Earth.

July 13, 2018

The Karlsruhe Tritium Neutrino Experiment, or KATRIN, is a massive detector based in the town of Karlsruhe, Germany, that has been designed to measure a neutrino’s mass with far greater precision than existing experiments.

3 Questions: Pinning down a neutrino’s mass

KATRIN experiment investigates the ghostly particle.

June 8, 2018

Bottom view of the 19 CUORE towers installed in the cryostat.

Scientists report first results from CUORE neutrino experiment

Data could shed light on why the universe has more matter than antimatter.

March 26, 2018

Physicists at MIT have designed a pocket-sized cosmic ray muon detector to track these ghostly particles.

Physicists design $100 handheld muon detector

Pocket-sized device detects charged particles in surrounding air.

November 20, 2017

Researchers have observed a novel phenomenon in sheets of tantalum arsenide that mimics the behavior of theorized (but never observed) particles called Weyl fermions.

Exploring elusive high-energy particles in an unusual metal

Exotic metal displays behavior that could lead to new infrared detectors.

May 30, 2017

The IceCube Neutrino Observatory is a huge, cubic-kilometer particle detector buried deep under the ice at the South Pole. After analyzing 20,000 neutrinos detected over the span of a year at the observatory, scientists were unable to observe any sign of sterile, or “hidden,” neutrinos.

Neutrino search finds no evidence of “hidden” particle

If discovered, sterile neutrinos may explain dark matter.

August 8, 2016

MIT physicists have found that subatomic particles called neutrinos can be in superposition, without individual identities, when traveling hundreds of miles, and not just at quantum, subatomic scales.

MIT scientists find weird quantum effects, even over hundreds of miles

Neutrinos traveling 450 miles have no individual identities, according to MIT analysis.

July 19, 2016

3Q: The massive impact of neutrino research

Physicist Joseph Formaggio discusses the significance of this year’s Nobel Prize in physics, MIT’s involvement in neutrino research.

October 6, 2015

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