The project consists of three interconnected activities: developing advanced identification methods of particles in the Belle II detector, studying departures from Lepton Flavour Universality (a theoretical prediction that all species of charged leptons interact uniformly with quarks) in decays of B and D mesons, and exploring processes completely forbidden within the current theoretical description of the elementary particle interactions (Standard Model).
The developing methods for identifying leptons, pions, and kaons has been the primary research focus in the initial project phase as it lays the foundation for advancements in the other two packages. Notably, a new method has been developed for separating low-momentum electrons, muons, and pions, utilizing Machine Learning techniques, specifically a Convolutional Neural Network (CNN), to analyze patterns in the electromagnetic calorimeter. Results of a detailed study of the Cherenkov light radiated by pions and kaons has been conducted were incorporated into an algorithm that improves particle type differentiation.
The core research theme of the project is the study of departures from Lepton Flavour Universality. The enhanced particle identification capabilities were used in developing B and D mesons tagging and reconstruction methods. Several reports have been accepted for publication, including novel methods for identifying the production flavor of neutral charmed and beauty mesons. B-meson decays were studied that involve a tau lepton and a light meson (a pion or a rho meson) in the final state, optimizing event selection criteria, and comparing simulated and measured data.
We have also started a promising new avenue for checking lepton flavor universality through the measurement of the rates of decays of B mesons into any hadron, composed of a charm quark, and either an electron, muon or a tau lepton. The initial feasibility study showed promising results, and a new postdoctoral researcher joined the team to strengthen this challenging measurement.
Within the third activity, research is being conducted on exotic processes, forbidden in the Standard Model, where lepton flavor number or baryon number are not conserved. Here we searched for a B meson decay into a kaon, accompanied by an electron and a tau lepton (lepton flavour number not conserved). A preparatory study for decays in which baryon number (number of heavy particles composed of three quarks like a proton) is not conserved has also been carried out.