On Superposition and Entanglement of Polarized Photons Without Hidden Variables

Polarized photons have properties that can be explained, among others, by their indistinguishability. This includes superposition and entanglement. We propose that the superposition state can be understood as the entirety of all mixtures of indistinguishable perpendicularly polarized photon beams. The photon beams, whose polarization correspond to the position of the polarizer, are filtered out by selection using a polarizer. There are no nonlocal effects with the entangled photons. This is because the physical states of the photons are defined before each measurement. The model replicates the predictions of quantum mechanics for entangled photons and also explains entanglement swapping and teleportation. The superposition of indistinguishable photon beams can be experimentally demonstrated using a Mach-Zehnder interferometer. This explains how the polarization of the input state reappears at the output of the Mach-Zehnder interferometer.