New Physics in Flavour Observables

Abstract

LHCb found hints for physics beyond the Standard Model (SM) in B K*μ+μ-, R(K) and Bsφμ+μ-. These intriguing hints for NP have recently been confirmed by the LHCb measurement of R(K*) giving a combined significance for NP above the 5\,σ level. In addition, the BABAR, BELLE and LHCb results for B D(*)τ also point towards lepton flavour universality (LFU) violating new physics (NP). Furthermore, there is the long-standing discrepancy between the measurement and the theory prediction of the anomalous magnetic moment of the muon (aμ) at the 3\,σ level. Concerning NP effects, b sμ+μ- data can be naturally explained with a new neutral gauge bosons, i.e. a Z but also with heavy new scalars and fermions contributing via box diagrams. Another promising solution to b sμ+μ-, which can also explain B D(*)τ, are leptoquarks. Interestingly, leptoquarks provide also a viable explanation of aμ which can be tested via correlated effects in Zμ+μ- at future colliders. Considering leptoquark models, we show that an explanation of B D(*)τ predicts an enhancement of b sτ+τ- processes by around three orders of magnitude compared to the SM. In case of a simultaneous explanation of B D(*)τ and b sμ+μ- data, sizable effects in b sτμ processes are predicted.