Rayleigh Scattering into Aikyon Gauge Field Lorentz Bosons in Emergent General Relativity

Virtual Lorentz bosons cause local gauge gravity and spacetime curvature causes general relativity non-locally. The quaternionic classical limit to Bell’s famous theorem identifies fermion produced torsion as locally emergent general relativity. The resulting renormalized Schwarzschild action defines a conserved mass and general relativity becomes a local standard model gauge field. Dirac electrons produce torsion that locally parallelizes aikyon quaternionic space as observed by a single Rayleigh scattering photon. The aikyon quaternionic SL(2,C) gauge field is mediated by the Lorentz boson that minimally couples to localized fermion number at gravitational strength. A Rayleigh scattered photon does not minimally couple to the emergent gauge general relativity and must vanish to preserve the principle of equivalence. The non-Hermitian Schrödinger wave equation simply changes a Rayleigh scattered photon into the particle vacuum, preserving the principle of equivalence. The continuum limit in emergent general relativity enables a Lorentz boson to absorb the reaction energy of a single Rayleigh scattering photon and a Planck mass worth of silica molecules to absorb electron-fermion localization backreaction energy, putting the aikyon Rayleigh scattering interaction on-shell.