Semiclassical computation of quantum effects in multiparticle production at large lambda n
Abstract
We use the semiclassical formalism based on singular solutions in complex time to compute scattering rates for multiparticle production at high energies. In a weakly coupled scalar field theory in four dimensions, we consider scattering processes where the number of particles in the final state approaches its maximal value , where is the particle mass. Quantum corrections to the known tree-level amplitudes in this regime are characterised by the parameter and we show that they become large at sufficiently high multiplicities. We compute full amplitudes in the large limit on multiparticle mass thresholds using the thin-wall realisation of the singular solutions in the WKB approach. We show that the scalar theory with spontaneous symmetry breaking, used here as a simplified model for the Higgs sector, leads to exponentially growing multi-particle rates within our regime which is likely to realise the high-energy Higgsplosion phenomenon. We also comment on realisation of Higgsplosion in dimensions lower than four.
Cite
@article{arxiv.1806.05648,
title = {Semiclassical computation of quantum effects in multiparticle production at large lambda n},
author = {Valentin V. Khoze},
journal= {arXiv preprint arXiv:1806.05648},
year = {2019}
}
Comments
35 pages, 7 figures. This paper a substantial update of my earlier article arXiv:1705.04365. v3: improved presentation of the calculation in new sections 5 and 6