Emerging Nonlocal Källèn-Lehmann Higgs Spectra at the LHC

Abstract

Electroweak symmetry breaking may arise from emergent nonlocal Källèn-Lehmann spectral densities in Hamiltonians with multiscalar interactions. The nonlocality scale ΛNL emerges naturally from the exponentially increasing degeneracy of mass eigenstates in the Higgs two-point function at scales p2 ≥ Λ2NL. Following the renormalization of the nonlocal Higgs propagator, we provide a framework for deriving analytic expressions for non-perturbative scattering amplitudes. We demonstrate that for energies exceeding the nonlocality scale, scattering amplitudes are exponentially suppressed. Furthermore, the real part of the Higgs self-energy is suppressed at deep spacelike momenta (p2 -Λ2NL), offering a solution to the Hierarchy problem. Such nonlocal scalar sectors are accessible to current and future LHC runs. We argue that the nonlocal Källèn-Lehmann spectral density can be constrained through a simultaneous global fit of LHC measurements in exclusive channels, including di-Higgs, electroweak di-boson, and di-photon production. This approach represents a paradigm shift in the search for new physics at high-energy colliders.