Simulated Interactions Between Radio Galaxies and Cluster Shocks -- 2: Jet Axes Orthogonal to Shock Normals.

We report a 3D MHD simulation study of the interactions between galaxies and galaxy-cluster-media shocks in which the incident shock normals are orthogonal to the bipolar AGN jets. Before shock impact, light, supersonic jets inflate lobes (cavities) in a static, uniform ICM. We examine three AGN activity scenarios: 1) continued, steady jet activity; 2) jet source cycled off coincident with shock/radio lobe impact; 3) jet activity ceased well before shock arrival (a radio phoenix scenario). The simulations follow relativistic electrons (CRe) introduced by the jets, enabling synthetic synchrotron images and spectra. Such encounters can be decomposed into an abrupt shock transition and a subsequent long term post shock wind. Shock impact disrupts the pre-formed, low density RG cavities into two ring vortices embedded in the post shock wind. Dynamical processes cause the vortex pair to merge as they propagate downwind somewhat faster than the wind itself. When the AGN jets remain active ram pressure bends the jets downwind, generating a narrow angle tail morphology aligned with the axis of the vortex ring. The deflected jets do not significantly alter dynamical evolution of the vortex ring. However, active jets and their associated tails do dominate the synchrotron emission, compromising the observability of the vortex structures. Downwind-directed momentum concentrated by the jets impacts and alters the post-encounter shock. In the radio phoenix scenario, no DSA of the fossil electron population is required to account for the observed brightening and flattening of the spectra, adiabatic compression effects are sufficient.