Tom Clarke states:
*The other side of this is that nuclear reactions, once they happen, have multiple paths all of which result in high energy released, and therefore high energy products. The energies here are MeV typically. Some paths also result in neutrons released which whether high or low energy are easily detected - solitary neutrons are a no-no and neutrons can only stop being solitary by transmuting elements. * One advantage that the NiH reactor has over standard nanoplasmonic reactions is that there is a positive feedback loop with the transmuted atoms that brings the energy made available through nuclear reconfiguration of multiple hydrogen atoms into the soliton via a tight coupling of the magnetic field. The soliton absorbs this energy to grow stronger until it can no longer can absorb any more reaction energy; the polariton soliton then explodes in a "bosenova" which distributes it XUV energy for further thermalization. This explosion process has been experimentally observed and publicly reported by DGT.
