In the advancing field of high-order power systems, the strategic realization of absolute negative resistance represents a pivotal departure from classical dissipative models. Traditionally, inductive components are relegated to the role of passive storage elements, characterized by reactive impedance and inevitable ohmic losses. However, by manipulating the internal flux environment, we can transition toward an active, energy-modulating state that exhibits non-isentropic flux dynamics. This research explores the transition from standard cylindrical inductors to modified flux tube structures, where geometric anisotropy is leveraged to establish a persistent potential gradient. The primary objective is to utilize core geometry and flux continuity to achieve absolute negative resistance, redefining the inductor from a dissipative sink into a potential source of radiation and power. This shift necessitates a rigorous re-examination of the magnetic flux tube as a fundamental unit of electrodynamic transport or the flow of magnetic monopoles.