In a trillion or so years’ time, the Universe will have exhausted all of its star-forming material. The last star will be born and from thereon the Universe will face a slow death as gradually each and every star burns out. Fermilab’s Dan Hooper discusses how life will struggle to survive into the deep future but dark energy is intent on stealing the stars 100–150 billion years into the future.

The New York Times reports on LBNF/DUNE. When DUNE operations begin, the research results could a major gap in scientists’ understanding of the universe and return the United States to its former position at the center of particle physics.

Theoretical physicist James D. “BJ” Bjorken, theoretical physicist at SLAC and Stanford, passed away on Aug. 6. He was born in Chicago and in 1979, he left the SLAC and Stanford faculties to become associate director for physics at the Fermilab, saying he wanted to learn more about the accelerator side of things

There are patterns seen in quarks and leptons that remain unexplained, but it can be hypothesized that quarks and leptons might be created of still smaller particles. Does the Standard Model allow for an even smaller layer of matter to exist?

Fermilab scientists have taken a major step in preparing for the Deep Underground Neutrino Experiment with a prototype particle accelerator. The 2×2 detector prototype has four liquid argon modules arranged in a square whereas the DUNE detectors will have 35 liquid argon time projection chambers, allowing scientists to track the movements of particles and determine their physical properties.

The prototype of a novel particle detection system for the international Deep Underground Neutrino Experiment successfully recorded its first accelerator neutrinos, providing a first look at the ability of this innovative technology to handle large numbers of the mysterious particles’ interactions.

Listen to the podcast story of Dr. Helen Edwards, who was a Fermilab particle physicist who led the design and construction of the Tevatron to probe deeper into the atom than anyone had gone before.

Neutrinos were first detected by Los Alamos researchers in 1956 and today very little is known about these elusive particles. Today, Los Alamos is part of the international collaboration of DUNE which aims to launch the most intense neutrino beam in the world.

Fermilab has twin laboratories that will probe superconducting qubits: QUIET is a new detector 100 meters underground and its counterpart is on the surface called LOUD, which began operations in 2022. The differences between the two detectors’ observations will allow researchers to assess how cosmic radiation affects qubit performance.

The unusually large Muon has threatened the Standard Model for decades, but new data parks the particle inside the confines of established physics. The BMW Collaboration’s recently posted research suggests the difference between the muon’s predicted anomalous magnetic moment and that predicted by the Standard Model is not as large as previous findings suggested.