Event Description
David Flay, PhD, University of Massachusetts, Amherst
The Standard Model of particle physics describes the properties and interactions of all known subatomic particles in the universe, but is known to be incomplete. There are many frontiers looking for the missing pieces to the puzzle, including new particle searches at the Large Hadron Collider at CERN; dark matter searches across the world including the U.S., South America, and the U.K., and detailed studies of neutrino properties, particularly neutrino oscillations, to name a few. Precision tests of the Standard Model offer an alternative path to new physics searches. One of the most precise measurements in physics, the anomalous magnetic moment of the muon—commonly discussed in the literature as the muon anomaly aμ ≡ (gμ − 2)/2—remains a possible indicator of physics beyond the Standard Model. This is because the discrepancy between theory and experiment is roughly 3.5 standard deviations.
To address this discrepancy, a new experiment at Fermilab has been constructed and is now running to determine aμ to a precision of 140 parts per billion. To measure aμ, a polarized muon beam is injected into a 14-m diameter magnetic storage ring and two frequencies are measured: the rate at which the muon polarization rotates relative to its momentum, ωa, and the magnetic field normalized to the free-proton Larmor-precession frequency, ωp. In this talk, an overview of the experiment will be presented, along with an update on the current operations and analysis status.
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