Huge difference. Fusors are just Inertial electrostatic confinement fusion devices. This one here adds lattice confinement fusion to it (see NASA Glenn Research two Phys Rev C papers in 2023), ie you reach fuel densities 6 to 8 orders of magnitudes higher than in a plasma as you exploit electron screening in your metal lattice, plus binary packing in specific metal alloys. Anyone can build a fusor in a kitchen, but these guys combine two entirely different fusion mechanisms (IEC+LFC) which hasn't been done before. That way you get minimum 1E11 DT neutrons/s at source, and even higher fluxes once you start optimising the materials involved. A hard 14 MeV DT neutron generator with that high flux? A golden opportunity for testing future materialsand electronics in a harsh fusion environment.
A fusor does 1E6 n/s at best, and that'd be 2.45 MeV DD neutrons only, because obtaining a Tritium license is not trivial.
