The determination of the Higgs self-coupling is a key target for future colliders, in particular through di-Higgs production at e+e− Linear Colliders with s>450\,GeV, e.g.\ ILC, C3 or CLIC. This contribution will discuss the roles and the interplay of di-Higgs production processes at various collider energies, including the case of non-SM values of the self-coupling. Previous studies, already based on Geant4-based detector simulation, established that the Higgs self-coupling can be extracted with 10−27% precision and provided a solid understanding of the limiting factors. This provides a robust starting point to explore the potential of more modern and sophisticated reconstruction and analysis techniques. We summarize the impact of advanced, often machine-learning-based algorithms, including e.g.\ jet clustering, kinematic fitting and matrix element-inferred likelihoods on the reconstruction of ZHH events and before discussing the dependence of the projected precision on the center-of-mass energy and on the actual value of the self-coupling.
@article{arxiv.2411.01507,
title = {Higgs Self-coupling Strategy at Linear e$^+$e$^-$ Colliders},
author = {Bryan Bliewert and Jenny List and Dimitris Ntounis and Junping Tian and Julie Munch Torndal and Caterina Vernieri},
journal= {arXiv preprint arXiv:2411.01507},
year = {2024}
}
Comments
6 pages, contribution to proceedings of ICHEP 2024