An illustration of two neutron stars spinning around each other while merging.
NASA/CXC/Trinity University/D. Pooley et al.
Astronomers are now able to detect a host of signals streaming through the universe. This newfound ability is like gaining new senses and it's opening the door to understanding the cosmos.
A detector buried under more than a mile of ice in Antarctica has detected a high-energy subatomic neutrino and traced it to its origin, a blazar – a gargantuan black hole more than a billion times more massive than the sun.
Artist’s impression based on real picture of Icecube lab.
A giant detector at the South Pole has observed a neutrino from a black hole in a distant galaxy for the first time.
How does our world work on a subatomic level?
Varsha Y S
A particle physicist explains just what this keystone theory includes. After 50 years, it's the best we've got to answer what everything in the universe is made of and how it all holds together.
Looking up in the main chamber at SNOLAB’s facility in the Vale Creighton nickel mine in Sudbury, Ont., a giant spherical neutrino sensor array the size of a 10 storey building is used to detect subatomic particles that pass through the earth.
Deep underground, scientists research subatomic particles from space in a bid to understand the building blocks of our universe.
The Deep Underground Neutrino Experiment (DUNE) could help unravel the mysteries of antimatter and complete scientists' next model of the universe.
A burst of ghostly neutrinos may have been generated by a quasar like this.
A burst of neutrinos detected deep under the Antarctic ice may have originated from a distant quasar on the edge of the visible universe.
Neutrinos, we’re looking for you! Japan’s Super-Kamiokande detector.
Kamioka Observatory, ICRR (Institute for Cosmic Ray Research), The University of Tokyo
The Nobel Prize-winning research on neutrinos is expected to push the boundaries of science and technology.