Quantum computers using photons and electrons.
Photons have spin-1, electron 1/2. Meaning you could condense the number of way electrons at certain speeds and qutrits by using photons to cancel out the spin of unneeded number increasing output speed. At least for spun waves.
Quantum entanglement means there would be a -1/2, +1/2 electron spin. If a proton was spun at it +1 it would become 1/2 and +1.5 for the +1/2, while a quantum entangled proton with -1 become -1.5, -1/2. Meaning you could divert three +/-1 times the number of electrons into the proton entanglement getting up to 4 times the output (certainty of randomness?) As the single entanglements would negate to zero or be interfered again with light.
Would it also mean that if the entangle particles collapsed before the photon affected ones did you would lose the effect of their interaction or would the new state remain constant to become something useable as a boundary box for the qubit and qutrits inside?
Especially if you combine layering of qutrits and qubits.
Couldn’t you arrange the three in staggered stages so that as they collapse in their given direction the peaks combined with the spun protons carry information further into the system juicing the qubits and qutrits much further than pure quantum entanglement.
Need to learn about the Bell states more. And Not gates.
So this doesn’t include all not gates drawn nor regular gates drawn but to give an idea of what photons could do increasing the spin of an electron without being an electron spun up to light speed (cooling advantage. May be able to run off new leds). But we have
14 1.5 transactions. (1/2, -1.5, -1/2, +1/2)
12 1/3 transactions. (1 1/3, -2/3, -1/3, +1/3)
56 1/2 transactions. (28 1/2, 28 -1/2)
Of which the
1.5, 1.3, 2/3, 1/3, 1/2 positives also have
-1.5, -1.3, -2/3, -1/3, -1/2 negatives.
Some of bonds are due to quantum entanglement and could create new reversible and non reversible gate types as well as length the entanglement between bits as they are produced.
Then again couldn’t quantum dots be shown down through a material to not expend as much heat and you run it off various leds types and it’s a room temperature quantum computer.
Quantum dot gets excited and releases electron into conductance band first into the system to get electron spin then lowered back to valence band to get (with uv help) emitting light so you can get different size quantum artificial atoms as well as colors for emittance. Multilayered quantum computing at the true speed of quantum dots light limited by uv pulse output.
Just an idea.