Learning S-Matrix Phases with Neural Operators
This work introduces a novel methodology for theoretical physics by applying neural operators to a regression-classification task in scattering theory, potentially aiding in amplitude analysis.
The researchers tackled the problem of predicting the phase of scattering amplitudes from their modulus using Fourier Neural Operators, achieving accurate predictions for infinite partial wave expansions and developing a classifier that correlates with unitarity violations.
We use Fourier Neural Operators (FNOs) to study the relation between the modulus and phase of amplitudes in $2\to 2$ elastic scattering at fixed energies. Unlike previous approaches, we do not employ the integral relation imposed by unitarity, but instead train FNOs to discover it from many samples of amplitudes with finite partial wave expansions. When trained only on true samples, the FNO correctly predicts (unique or ambiguous) phases of amplitudes with infinite partial wave expansions. When also trained on false samples, it can rate the quality of its prediction by producing a true/false classifying index. We observe that the value of this index is strongly correlated with the violation of the unitarity constraint for the predicted phase, and present examples where it delineates the boundary between allowed and disallowed profiles of the modulus. Our application of FNOs is unconventional: it involves a simultaneous regression-classification task and emphasizes the role of statistics in ensembles of NOs. We comment on the merits and limitations of the approach and its potential as a new methodology in Theoretical Physics.