Abstract
Anomalous magnetic moment of the muon (muon g-2) is one of the most precisely measured quantities in particle physics. At the same time, it can be evaluated in the Standard Model with an unprecedented accuracy. The Muon g-2 experiment at Fermilab has started the major data collection and the aimed four-fold increase in precision will shed light on the current discrepancy between the theory prediction and the measured value. This renders a comparable improvement of the precision in the SM theory an essential ingredient in order to fully exploit the expected increase of precision in experimental results. For all these reasons, the muon g-2 is considered to be a great testing ground for new physics.Hadronic contributions are the dominant sources of uncertainty in the theoretical prediction of the muon g-2. A reciprocal effort to a precise determination of the leading hadronic contribution to the muon g-2 using lattice gauge theories is a direct measurement of the hadronic contributions to the running of the fine structure constant recently proposed by the MUonE experiment. A hybrid strategy including both experimental and lattice data sets is expected to give an independent check of the dispersive results from e+e-annihilation, which dominate the current world average.
Highlights
Muon magnetic moment represents one of the most sensitive tests of the Standard Model (SM), as this observable can be extremely accurately measured in the experiment and it is predicted in SM with high precision
Exchanging the order of x and s integrations in Eq 2 leads to the form of the space-like integral commonly used for lattice QCD evaluations of the leading hadronic contribution to the muon g-2: aHμ LO =
The preliminary result of the intermediate integral I1 reported here gives a first estimate on Nf = 2 ensembles using O(a) improved Wilson fermions
Summary
Muon magnetic moment represents one of the most sensitive tests of the Standard Model (SM), as this observable can be extremely accurately measured in the experiment and it is predicted in SM with high precision. The improved accuracy in the leading hadronic contribution to the muon g − 2 can be achieved by combining experimental input from R-ratios with the lattice QCD data [6, 7]. Method to calculate aHμLO with experimental input from direct measurement of the hadronic part of the photon vacuum polarization (Dahad(q2)) in the spacelike region has been proposed [3]. As it can be seen, Left, the real part of the photon vacuum polarization is a smooth function in the spacelike domain (i.e. at negative squared momentum transfer), contrary to the timelike behavior where it undergoes significant variations due to the presence of resonances and threshold effects
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