From Forbes, April 7, 2021: Don Lincoln, senior scientist at Fermilab, explains that a new measurement announced by Fermilab last week goes a long way towards telling us if the venerable theory will need revising.

From New Scientist, April 7, 2021: The strange behavior of a fundamental particle called a muon may hint at the existence of exotic particles and forces beyond the standard model of physics.

From CNN, April 7, 2021: Fermilab’s senior scientist Don Lincoln explains the Muon g-2 experiment’s single measurement tells scientists the standard model of particle physics is incomplete — and has to be rethought.

From National Geographic, April 8, 2021: In a landmark experiment, a collaboration of scientists led by Fermilab has found fresh evidence that a subatomic particle is disobeying one of science’s most watertight theories, the Standard Model of particle physics.

From the Associated Press, April 7, 2021: Fermilab announced results Wednesday of 8.2 billion races along a track that have physicists astir: The muons’ magnetic fields don’t seem to be what the Standard Model says they should be.

From The New York Times, April 7, 2021: A collaboration of scientists led by Fermilab announced mounting evidence that a tiny subatomic particle seems to be disobeying the known laws of physics.

The first results from the Muon g-2 experiment hosted at Fermi National Accelerator Laboratory show fundamental particles called muons behaving in a way not predicted by the Standard Model of particle physics. These results confirm an earlier experiment of the same name performed at Brookhaven National Laboratory. Combined, the two results show strong evidence that our best theoretical model of the subatomic world is incomplete. One potential explanation would be the existence of undiscovered particles or forces.

What does it take to envision and build a seemingly impossible particle accelerator? The results of these discussions will shape the next 100 years of particle physics research.

On March 17, Fermilab and Argonne hosted a virtual “Doing Business with Your National Labs” meeting. The event drew nearly 200 diverse small business leaders who came to hear about how to prepare and submit proposals for contracts.

To fully realize the potential of quantum computing, scientists must start with the basics: developing step-by-step procedures, or algorithms, for quantum computers to perform simple tasks. A Fermilab scientist has done just that, announcing two new algorithms that build upon existing work in the field to further diversify the types of problems quantum computers can solve.