Probing few-body nuclear dynamics via 3H and 3He (e,e'p)pn cross-section measurements.

We report the first measurement of the (e,e'p) three-body breakup reaction cross sections in Helium-3 ($^3$He) and Tritium ($^3$H) at large momentum transfer ($ ~ 1.9$ (GeV/c)$^2$) and $x_B > 1$ kinematics, covering a missing momentum range of $40 \leq p_{miss} \leq 500$ MeV/c. The measured cross sections are compared with different plane-wave impulse approximation (PWIA) calculations, as well as a generalized Eikonal-Approximation-based calculation that includes the final-state interaction (FSI) of the struck nucleon. Overall good agreement is observed between data and Faddeev-formulation-based PWIA calculations for the full $p_{miss}$ range for $^3$H and for $150 \leq p_{miss} \leq 350$ MeV/c for $^3$He. This is a significant improvement over previous studies at lower $Q^2$ and $x_B \sim 1$ kinematics where PWIA calculations differ from the data by up to 400%. For $p_{miss} \geq 250$ MeV/c, the inclusion of FSI makes the calculation agree with the data to within about 10%. For both nuclei PWIA calculations that are based on off-shell electron-nucleon cross-sections and exact three-body spectral functions overestimate the cross-section by about 60% but well reproduce its $p_{miss}$ dependence. These data are a crucial benchmark for few-body nuclear theory and are an essential test of theoretical calculations used in the study of heavier nuclear systems.