Thorne-\.{Z}ytkow objects (T\.{Z}Os), hypothetical merger products in which a central neutron star powers a stellar envelope, are traditionally considered steady-state configurations, though their assembly, especially through dynamical channels, is not well-understood. The predominant focus in the literature has been the observational signatures related to the long-term fate and evolution of T\.{Z}Os, with their initial formation often treated as a given. However, the foundational calculations supporting the existence of T\.{Z}Os assumed non-rotating, spherically symmetric initial conditions that are inconsistent with a merger scenario. In this work, we explore the implications of post-merger dynamics in T\.{Z}O formation scenarios with field binary progenitors, specifically the role that angular momentum transport during the common envelope phase plays in constraining possible merger products, using the tools of stellar evolution and three-dimensional hydrodynamics. We also propose an alternative steady-state outcome for these mergers: the thin-envelope T\.{Z}O. These potential X-ray sources would follow a series of bright transient events and may be of interest to upcoming time-domain surveys.
Comment: 13 pages, 8 figures, Submitted to ApJ