A radioactive mass that decays from a neutron to a proton (loss mass) can be a positive gravity particle conductor.
Just as you might think my insanity is not complete...
If a fan feels cooling because \(T^{-}\) particles gain greater momentum before the fan under the action of gravity \(g\), where in part the variation in \(g\), \(\cfrac{\partial\,g}{\partial t}\) is due to the fan oscillating from side to side that throws the \(T^{-}\) particles into a Coriolis path and that \(g\) is a standing wave with a low frequency along the flow of \(T^{-}\).
\(T^{+}\) can be retarded by the addition of an \(E\) field pointing backwards. The change in \(E\), \(\cfrac{\partial\,E}{\partial t}\) needed is provided for by the side to side rotation of the fan. The air current before the fan will even be more cooling.
The underlying principle of accelerating temperature particles can be easily tested by reversing the rotation of the fan blades but still pushing air forward. The fan will then be more cooling behind, where there is no perceivable air flow, than in front, in the path of the air current. (It is assumed here that, \(T^{+}\) particles with energy oscillating along \(t_c\), are able to excite valence electrons upon collisions and so affect the rate of chemical reactions. These are the particles we feel as heat.)
Air conditioning on the cheap.