Name: [sém. doct.] Killian Martineau "Gravitation quantique à boucles dans l'univers primordial et les trous noirs", Kseniia Svirina "Collider phenomenology of BSM Higgs physics"
Start: 2018-04-03T10:00:00+02:00
End: 2018-04-03T11:00:00+02:00
Location: No location set

Description

Killian Martineau "Gravitation quantique à boucles dans l'univers primordial et les trous noirs", Le secteur cosmologique apparaît comme la voie la plus prometteuse pour tester et contraindre des théories de gravitation quantique. La Gravitation Quantique à Boucles (LQG) constitue quand à elle une des tentatives les plus avancées de quantification non perturbative de la relativité générale. Sa version à symétries réduites, la Cosmologie Quantique à Boucles (LQC), possède des prédictions claires à la fois pour la dynamique du fond et celle des perturbations. Notamment la singularité initiale du Big Bang est remplacée par un rebond dû aux effets de gravitation quantique. Dans cette présentation j’introduirai rapidement la LQG et la LQC et discuterai de la manière dont ces théories peuvent être reliées à des observations cosmologiques. J’aborderai également le cas des trous noirs dans ce même contexte. Kseniia Svirina "Collider phenomenology of BSM Higgs physics", The Standard Model (SM) of the particle physics describes successfully almost all existing experimental data, however it has certain deficiencies such as the hierarchy problem, namely, the SM cannot explain the large discrepancy between the weak energy scale and the Planck mass scale. For this reason various theories beyond the SM are of interest nowadays and the evidences of a New physics аrе anticipated close to the electroweak scale, accessible at the LHC. One of the parameters sensitive to the deviations from the SM is the trilinear Higgs coupling, and the key process for its verification is the Higgs pair production. In particular, such a deviation can occur due to the presence of another scalar particle (the radion) appearing in models with extra dimensions (e.g. the Randall-Sundrum (RS) model that provides a t solution of the hierarchy problem). We have implemented the RS model in the FeynRules package, achieving an automated calculation of the underlying Feynman rules with a prospective to interface the model file with MadGraph for study of collider phenomenology of the model (scalar pair production, Higgs couplings). These processes are also important for reconstructing the Higgs potential and studying its stability. The latter, for any model, requires the knowledge of the running of the model parameters i.e. the link between the low and the high energy scales. For this purpose a profound study of the renormalization group equations (RGE) is in progress.