The project started with a pilot study, designed to aid a direct search for NP within a class of super-symmetric models. We predicted certain mass-ratios within theories with a large number of "colours" and one "quark flavour". In the event of one new particle being discovered at an experiment, these ratios predict further experimentally detectable particles. Depending on whether or not the experiment subsequently finds another particle with the correct mass ratio, our work can be used to test whether the discovered new particle can be explained by this type of theory or not. We explored the relevant parameter space and established a computational set-up that we will use to refine this study in the future as more computing resources become available. First results have been presented at several conferences (Lattice 2021 and 2022, 1st and 2nd Nordic Lattice Meeting) and workshops, have been published in proceedings and will soon be submitted for a journal publication.
Through the pilot study we gained familiarity with the code base we are using for the heavy quark part of the project. Based on this experience we explored and optimised a computational set-up which allows us to make the best use of the existing gauge field configurations to which we have access. These results have been presented at Lattice 2022 and the 2nd Nordic Lattice Meeting and will soon be published as conference proceedings. We are now starting large scale simulations for several quark masses, space-time volumes and lattice spacings (smallest distance in the space-time grid) that will allow for the controlled prediction of a wide range of observables.
Simultaneously, we explored the numerical implementation of isospin breaking effects in the formulation of massive QED. This formulation has the advantage of being a valid causal Quantum Field Theory and computationally affordable and usable on pre-existing publicly available configurations. In order to scan the accessible parameter space of this formulation, we explored a wide range of choices, such as simulated photon masses and space-time volumes on existing gauge field configurations. We confronted our numerical computations with effective field theory based expectations, in order to confirm the viability of this method. Results of this feasibility study have been presented at Lattice 2021 and Lattice 2022 as well as the 1st and 2nd Nordic Lattice meeting and several seminars and workshops. First results have been published as conference proceedings and a journal publication is forthcoming. Based on this feasibility study, we have extended our computation to a wide range of ensembles with different quark masses, volumes and lattice spacings enabling the extrapolation of our results to physical parameters in a controlled fashion. We anticipate timely predictions of the experimentally known mass splittings. With data production already underway, we are currently extending our computation of isospin breaking effects to further highly relevant observables such as the anomalous magnetic moment of the muon, leptonic and semi-leptonic decay rates and the nucleon axial charge gA.
