Deep inelastic vortex scattering: A third outcome for head-on collisions

Abstract

Results are presented from numerical simulations of the flat-space nonlinear Maxwell-Klein-Gordon equations demonstrating deep inelastic scattering of m=1 vortices for a range of Ginzburg-Landau (or Abelian-Higgs) parameters (), impact parameters (b), and initial velocities (v0). The threshold (v0*) of right-angle scattering is explored for head-on (b=0) collisions by varying v0. Solutions obey time-scaling laws, T α(v0-v0*) , with -dependent scaling exponents, α, and have v0* that appear not to have the previously reported upper bound. The arbitrarily long-lived static intermediate attractor at criticality (v0=v0*) is observed to be the -specific m=2 vortex solution. Scattering angles are observed for off-axis (b≠ 0) collisions for a wide range of b, v0, and . It is shown that for arbitrarily small impact parameters (b→ 0), the unstable %but arbitrarily long-lived -dependent m=2 "critical" vortex is an intermediate attractor and decays with a -independent scattering angle of 135, as opposed to either of the well-known values of 180 or 90 for b=0.