Caustics in quantum many-body dynamics

Caustics are a striking phenomena in natural optics and hydrodynamics: high-amplitude characteristic patterns that are singular in the short wavelength limit. We use exact numerical and approximate semiclassical analytic methods to study quantum versions of caustics that form in Fock space during far-from-equilibrium dynamics following a quench in the Bose Hubbard dimer and trimer models. Due to interparticle interactions, both models are nonlinear and the trimer is also nonintegrable. The caustics exhibit a hierarchy of morphologies described by catastrophe theory that are stable against perturbations and hence occur generically. The dimer case gives rise to discretized versions of folds and cusps which are the simplest two of Thom's catastrophes. The extra dimension available in the trimer case allows for higher catastrophes including the codimension-3 hyperbolic umbilic and elliptic umbilic catastrophes which we argue are organized by, and projections of, an 8-dimensional corank-2 catastrophe known as $X_9$. These results indicate a hitherto unrecognized form of universality in quantum many-body dynamics organized by singularities.