On relativistic harmonic oscillator

Abstract

A relativistic quantum harmonic oscillator in 3+1 dimensions is derived from a quaternionic non-relativistic quantum harmonic oscillator. This quaternionic equation also yields the Klein-Gordon wave equation with a covariant (space-time dependent) mass. This mass is quantized and is given by m*n2=mω2(nr2-1-β\,(n+1))\,, where mω=ωc2\,, β=2mc2\,ω\, , n, is the oscillator index, and nr is the refractive index in which the oscillator travels. The harmonic oscillator in 3+1 dimensions is found to have a total energy of E*n=(n+1)\,\,ω, where ω is the oscillator frequency. A Lorentz invariant solution for the oscillator is also obtained. The time coordinate is found to contribute a term -12\,\,ω to the total energy. The squared interval of a massive oscillator (wave) depends on the medium in which it travels. Massless oscillators have null light cone. The interval of a quantum oscillator is found to be determined by the equation, c2t2-r2=λ2c(1-nr2), where λc is the Compton wavelength. The space-time inside a medium appears to be curved for a massive wave (field) propagating in it.