The Relativistic Levinson Theorem in Two Dimensions

Abstract

In the light of the generalized Sturm-Liouville theorem, the Levinson theorem for the Dirac equation in two dimensions is established as a relation between the total number nj of the bound states and the sum of the phase shifts ηj( M) of the scattering states with the angular momentum j: ηj(M)+ηj(-M)~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ \~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ~~~=\arrayll (nj+1)π & when~a~half~bound~state~occurs~at~E=M ~~ and~~ j=3/2~ or~-1/2\\ (nj+1)π & when~a~half~bound~state~occurs~at~E=-M~~ and~~ j=1/2~ or~-3/2\\ njπ~& the~rest~cases . array . The critical case, where the Dirac equation has a finite zero-momentum solution, is analyzed in detail. A zero-momentum solution is called a half bound state if its wave function is finite but does not decay fast enough at infinity to be square integrable.

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