As you can check from the detailed measurements (12 meters) (1600 meters), it is
not apparent immediately that there is on ongoing quantum transmission because the
de-excitation of the “slave” Indium foil (the one that is not stimulated and which
is measured) is very random on a counts per minutes basis while decreasing according
to the half life of the metastable state of the isomer nuclide (here, an Indium Foil).
As you can see, in order to notice the Macroscopically Induced Quantum Entangled
Transmission (MIQET), you have to apply a moving average (12 meters) (1600 meters)
removing some of the randomness of individual counts per minutes.
Our set-ups differ from the previous experimental set-ups and it is possible to provide
hypothesis on why entanglement is working on a macroscopic scale in the present case:
Many past set-ups relied on particle level entanglement such as two entangled photons.
On the contrary, our entanglement set-ups involve the preparation of samples comprising
metastable isomer nuclide materials, which are irradiated by entangled radiations
(for example coming from the Bremsstrahlung of accelerated electrons hitting a Tungsten
target or from a Cobalt source).
