Relativistic wave equations

Abstract The classical relativistic connexion between the energy pt of a free article and its momentum px, py, pz, namely, pt2 — px2 — py2 — pz2 — m2 = 0, (1) leads in the quantum theory to the wave equation pt2 — px2 — py2 — pz2 — m2 ψ = 0, (2) where the p's are understood as the operators iħ ∂/∂t, — iħ ∂/∂x. . The general theory of the physical interpretation of quantum mechanics requires a wave equation of the form pt — H ψ = 0, (3) where H is a Hermitian operator not containing pt, and is called the Hamiltonian. The obvious equation of the form (3) which one gets from (2), namely, pt — (px2 + py2 + pz2 + m2) ½ ψ = 0, is unsatisfactory on account of the square root, which makes the application of Lorentz transformations very complicated. By allowing our particle to have a spin, we can get wave equations of the form (3) which are consistent with (2) and do not involve square roots. An example, applying to the case of a spin of half a quantum, namely, the equation pt + αxpx + αypy + αzpz + αmm ψ = 0, (4) where the four α's are anti-commuting matrices whose squares are unity, is well known, and has been found to give a satisfactory description of the electron and positron. The present paper will be concerned with other examples, applying to spins greater than a half. The elementary particles known to present-day physics, the electron, positron, neutron, and proton, each have a spin of a half, and thus the work of the present paper will have no immediate physical application. All the same, it is desirable to have the equation ready for a possible future discovery of an elementary particle with a spin greater than a half, or for approximate application to composite particles. Further, the underlying theory is of considerable mathematical interest.