The total baryonic mass within a local Hubble volume, if collapsed into its most stable state (Fe-56), would form a single-nucleus-thick layer coating the surface of the global Hubble volume. In this configuration, the average distance between Fe-56 nuclei would closely approximate the electron's Compton wavelength. The energy released from collapsing hydrogen to Fe-56 is nearly sufficient to sustain an orbit at the global Hubble radius (about 1 in 1000 difference). The separation between the local and global Hubble radii is approximately defined by a particle accelerating at MOND's a0 over the Hubble time (see prior work). Thus, given infinite time in an instant, an "iron sky" would form. These characteristic distances arise from the direct product of the 26 sporadic groups (UNIVERSOID). This configuration holds only at approximately 13.8 billion years post-Big Bang under the Standard Model of Cosmology (SMoC). These findings challenge mainstream cosmology, raising further doubts about its validity.