Do Some Virtual Bound States Carry Torsion Trace?

TL;DR

This paper explores the possibility that certain virtual bound states in quantum physics carry the trace of affine torsion, drawing analogies from crystal dislocations and Einstein Cartan theory to suggest new insights into angular momentum conservation.

Contribution

It introduces the hypothesis that some virtual bound states may carry torsion trace, supported by analogies with crystal dislocations and Einstein Cartan theory.

Findings

Analogies between virtual bound states and dislocation geometry suggest torsion presence.

Hypothesized torsion in para-positronium could explain local angular momentum conservation.

Theoretical arguments support the potential role of torsion in quantum bound states.

Abstract

This article presents theoretical arguments that certain virtual bound states carry the trace component of affine torsion. The motivation for this work is that Einstein Cartan theory, which extends general relativity by including torsion to model intrinsic angular momentum, is becoming more credible. The author is not aware of any situation for which there is evidence or substantial argument for the presence of torsion trace, except in the continuum theory of edge dislocations in crystals. The main evidence for the hypothesis consists of analogies between the structure of virtual bound states and (a) geometry of dislocations in crystal lattices, which are modeled with torsion; and (b) modeling of intrinsic angular momentum by torsion in Einstein Cartan theory and the theory of microelasticity. The work focuses on conjectured presence of torsion in para-positronium, which intermediates annihilation of an electron and a positron with opposite z spins. If the virtual bound state carries torsion, then the local law of conservation of angular momentum can hold over the spacelike separation during annihilation.