The Ni/H reactor may be something new in science and technology because it is a macro quantum system; a quantum system where quantum mechanical properties become manifest on the macro level of the real world.
The dipoles that exist in the billions are easily synchronized through the exchange of infrared photons. When placed in the proper situation, these nickel and hydrogen dipoles want to oscillate in harmony and coherently rather than in random discord. This spontaneous coherent dipole ordering is what makes the Ni/H reactor special. This coherency is what gives the Ni/H reactor its various super powers. This coherent dipole motion makes a billion dipoles act as one. These billions of dipoles become one; a super-dipole. This unique feature brings the powers of the dipole that are only scene on the nano-level visible and felt in our macro world. This super-dipole builds on itself and becomes self-amplifying and perpetuating. The Ni/H reactor becomes super-fluid. Superfluidity makes heat equalize throughout the entire reactor volume were no hot or cold spots can exist. This tight thermal equilibrium tends to maintain and amplify coherent dipole motion. The solitons that form when dipoles encounter nano-particle boundary conditions also take on coherent behavior that is inherited from their dipole progenitors. The magnetic fields that these solitons produce are all quantum mechanically synchronized were billions of nano-magnetic fields combined together to form one super magnetic field. It is not necessary for the huge magnetic fields seen in the Ni/H reactor to come from a large current flow; the field is a perfect aggregation of billions of tiny solution entangled contributors. The exciting quantum mechanical question that we may now ask is “can a soliton take as well as give”; “does a given soliton inherit and concentrate the global magnetic power from all the other entangled solitons in its ensemble when it disrupts the subatomic particles that make up a given nucleus?”