The S-matrix bootstrap with neural optimizers I: zero double discontinuity
Abstract
In this work, we develop machine learning techniques to study nonperturbative scattering amplitudes. We focus on the two-to-two scattering amplitude of identical scalar particles, setting the double discontinuity to zero as a simplifying assumption. Neural networks provide an efficient parameterization for scattering amplitudes, offering a flexible toolkit to describe their fine nonperturbative structure. Combined with the bootstrap approach based on the dispersive representation of the amplitude and machine learning's gradient descent algorithms, they offer a new method to explore the space of consistent S-matrices. We derive bounds on the values of the first two low-energy Taylor coefficients of the amplitude and characterize the resulting amplitudes that populate the allowed region. Crucially, we parallel our neural network analysis with the standard S-matrix bootstrap, both primal and dual, and observe perfect agreement across all approaches.
Cite
@article{arxiv.2412.09610,
title = {The S-matrix bootstrap with neural optimizers I: zero double discontinuity},
author = {Mehmet Asim Gumus and Damien Leflot and Piotr Tourkine and Alexander Zhiboedov},
journal= {arXiv preprint arXiv:2412.09610},
year = {2024}
}
Comments
35 pages + appendices, 12 figures