Anatomy of prominent B and K decays and signatures of CP-violating new physics in the electroweak penguin sector

The recent observation of B_d → π⁰π⁰ at the B factories with a surprisingly large branching ratio represents a challenge for theory, and complements the amazingly small B_d → π⁺ π^-; rate. We point out that all puzzling B → π π features can be accommodated in the Standard Model (SM) through non-factorizable hadronic interference effects, extract the relevant parameters, and predict the CP asymmetries of B_d → π⁰ π⁰. Using then SU(3)flavour-symmetry and plausible dynamical assumptions, we fix the hadronic B → πK parameters through their B → π π counterparts, and determine the CKM angle γ, with a result in remarkable accordance with the usual fits for the unitarity triangle. We may then analyse the B → π K system in the SM, where we find agreement with the experimental picture, with the exception of those observables that are significantly affected by electroweak (EW) penguins, thereby suggesting new physics (NP) in this sector. Indeed, a moderate enhancement of these topologies and a large CP-violating NP phase allow us to describe any currently observed feature of the B → πK modes, and to predict the CP-violating B_d → π⁰ K_S observables. If we then restrict ourselves to a specific scenario where NP enters only through Z⁰ penguins, we obtain a link to rare K and B decays, where the most spectacular NP effects are an enhancement of the K_L → π⁰ νν̄ rate by one order of magnitude with Br(K_L → π⁰ νν̄) ≈ 4Br(K⁺ → π⁺ νν̄)), Br(K_L → π⁰ e⁺e^-) = O (10^-10, (sin 2β) _πνν̄ < 0, and a large forward-backward CP asymmetry in B_d → K* μ⁺ μ^-. We address also ε′/ε and other prominent decays, including B → φ K and B → J/ψ K modes.