The Limits of Mag-Chemistry
This manuscript presents a definitive theoretical analysis of the boundaries of mag-chemistry, moving beyond early exploratory frameworks to establish the rigorous physical laws governing multi-charged magatoms. By applying the Elementary Nucleus Paradigm—which posits that high-$Z$ magnuclei are single, indivisible particles whose physical size shrinks as mass increases ($r \propto 1/Z$)—we derive the $Z^7$ Atomic Density Scaling Law. This law reveals a violent spike in density as atomic number increases, culminating in a catastrophic event at $Z=12$: the Topological Collapse. We mathematically demonstrate that for all elements where $Z \ge 12$, the Bohr orbital radius falls inside the physical boundary of the nucleus, effectively ending chemical bonding. Consequently, we define the canonical Magmatter Periodic Table as an “Island of Stability” consisting of exactly eleven elements. This work highlights the role of Mag-Hydrogen ($Z=1$) as a unique metallic superconductor that facilitates lossless power transmission and high-performance computing, serving as the foundational building block for the most advanced magmatter technologies within the Schwarzschild limit. ...