Photon-induced molecular implementation of a quantized magnetic flux photoelectron

A fundamental magnetic flux quantum can be implemented into a free rotating molecule when the interacting molecular electron experiences the maximum possible intrinsic energy uncertainty of a gaussian, transform-limited half-cycle optical photon wavepacket. A magnetic flux resonance condition can be defined at this limit, with photoionization quenching, and the excited molecular electron is drawn into a Rydberg-like spherical surface where a 3D-diffraction pattern is oscillating at the minimum of a bound potential around a primary formed closed electronic loop. The induced rotational motion of the molecular ion core is initiated at the threshold of a robust inertial effect and the dissipated information entropy is the lowest allowed. The integrated quantum possibilities occur in the process as structural properties of a quantized magnetic flux implementation threshold.