When radio nucleotides undergo spontaneous stabilizing decay, energy is liberated from the nucleus. This energy occurs in Alpha, Beta and Gamma emission. The usable energy is coupled by means of a magnetic field associated with the charged particles moving at high velocities. Obviously, this process can return power when there exists a definite flux of the charged particles, suitably coupled. In order to ensure a highly collimated stream of charged particles becomes incident through the active coupling aperture, shadow collimate the source to produce a pencil beam or stimulate emission along a specific transverse axis. This technically simple geometric collimation reduces the available power from a source to a small aspect ratio. Stimulated gain allows for two enhancing attributes. It assures a high percentage of emission occurs along a specified axis and can produce higher fluxes of charged particles. The physical mechanism of stimulated decay utilizing precise injection of photons at energy/wavelengths of sub-nuclear scale. While the energy produced is very high, the power required is very low, the transfer in the space of B wavelength. The energy is recovered in the actual ejection coupling of the emitted particle. When the ejection takes place, the intensity of the flux can be entrained by the geometry of the active ejection region. This allows for a highly active and efficient small aperture coupling section. The total amount of energy available from any unstable source is fixed in MOST situations. ADEC does not change the mechanism of spontaneous decay, it changes the probability of which atoms will undergo decay and when the decay will occur. As atoms exhibit no statistical memory, the event of a neighboring atom's spontaneous decay in no way influence the likelihood or unlikelihood of decay of a selected atom. As the extraction of power from the nuclear material is accelerated, the materials natural emissive lifetime will be exhausted in direct relation.
APPLICATIONS: Nuclear Waste Disposal and Utilization Universal Power Source Co-generation Systems for Returning Power to Electrical Grids Primary Energy Sources for Instrumentation and Devices Space Platform Power Generation Critical Mass Aberration Medical Treatment Radiation Detection Instrumentation and Sensors Nuclear Imaging Techniques Short Wavelength Quantum Devices