The Energy Eigenvalue for the Singular Wave Function of the Three Dimensional Dirac Delta Schrodinger Potential via Distributionally Generalized Quantum Mechanics
Abstract
Unlike the situation for the 1d Dirac delta derivative Schrodinger pseudo potential (SPP) and the 2d Dirac delta SPP, where the indeterminacy originates from a lack of scale in the first and both a lack of scale as well as the wave function not being well defined at the support of the generalized function SPP; the obstruction in 3d Euclidean space for the Schrodinger equation with the Dirac delta as a SPP only comes from the wave function (the $L^2$ bound sate solution) being singular at the compact point support of the Dirac delta function (measure). The problem is solved here in a completely mathematically rigorous manner with no recourse to renormalization nor regularization. The method involves a distributionally generalized version of the Schrodinger theory as developed by the author, which regards the formal symbol "$H\psi$" as an element of the space of distributions, the topological dual vector space to the space of smooth functions with compact support. Two main facts come to light. The first is the bound state energy of such a system can be calculated in a wellposed context, the value of which agrees with both the mathematical and theoretical physics literature. The second is that there is then a rigorous distributional version of the HellmannFeynman theorem.
 Publication:

arXiv eprints
 Pub Date:
 January 2021
 arXiv:
 arXiv:2101.07876
 Bibcode:
 2021arXiv210107876M
 Keywords:

 Quantum Physics;
 Mathematical Physics;
 Mathematics  Analysis of PDEs;
 Mathematics  Functional Analysis;
 Mathematics  Spectral Theory;
 47B93 (Primary) 35D99;
 35J05;
 35J08;
 35J10;
 35Q40;
 35S05;
 46F10;
 46N50;
 81Q05;
 81Q65;
 81Q80;
 81V19 (Secondary)
 EPrint:
 10 pages total, 9 pages content, 1 page references