The Geometry of the Dirac Equation

## Abstract In this paper we consider bound state solutions, i.e., normalizable time‐periodic solutions of the Dirac equation in an extreme Kerr black hole background with mass __M__ and angular momentum __J__. It is shown that for each azimuthal quantum number __k__ and for particular values of __

The problem of solving the single-particle Dirac equation variationally in the geometry of a diatomic molecule is studied using a minimax formulation of the problem. The lowest two states in Hz are considered, as well as the problem of the motion of an electron in the field of two nuclei with Z= 90.

We prove that in the nonextreme Kerr-Newman black hole geometry, the Dirac equation has no normalizable, time-periodic solutions. A key tool is Chandrasekhar's separation of the Dirac equation in this geometry. A similar nonexistence theorem is established in a more general class of stationary, axis

The angular eigenvalue in equation (2.16) should not be an integer but a half odd integer. The reason is that the transformation V from the Dirac operator in the symmetric frame to the usual Dirac operator in polar coordinates given at the end of Section 2.1 has a change of sign at ϕ = 0. Likewise,

I show that solutions of the SU(∞) Toda field equation generating a fixed Einstein-Weyl space are governed by a linear equation on the Einstein-Weyl space. From this, obstructions to the existence of Toda solutions generating a given Einstein-Weyl space are found. I also give a classification of Ein

In this paper, we study first-order symmetric, hyperbolic systems of differential operator with constant coefficients on L p -spaces. We show that such systems can be governed by some C -semigroups and as an application we consider the Dirac equation. Our result improves that of Nicaise [S. Nicaise,