Supersymmetric Klein-Gordon and Dirac oscillators

TL;DR

This paper extends the relativistic oscillator model to a supersymmetric version, revealing a rich geometric structure and providing an exactly solvable, Lorentz covariant quantum Dirac oscillator framework with solutions in Bergman spaces.

Contribution

It introduces a supersymmetric relativistic oscillator model with a geometric phase space structure and derives an exactly solvable Dirac oscillator equation within this framework.

Findings

The covariant phase space of the supersymmetric oscillator is the odd tangent bundle of a Kähler-Einstein manifold.

Solutions form spinor spaces of holomorphic and antiholomorphic functions on the phase space.

The model is Lorentz covariant, unitary, and exactly solvable.

Abstract

We have recently shown that the space of initial data (covariant phase space) of the relativistic oscillator in Minkowski space $\mathbb{R}^{3,1}$ is a homogeneous K\"ahler-Einstein manifold $Z_6$=AdS$_7$/U(1)=U(3,1)/U(3)$\times$U(1). It was also shown that the energy eigenstates of the quantum relativistic oscillator form a direct sum of two weighted Bergman spaces of holomorphic (particles) and antiholomorphic (antiparticles) square-integrable functions on the covariant phase space $Z_6$ of the classical oscillator. Here we show that the covariant phase space of the supersymmetric version of the relativistic oscillator (oscillating spinning particle) is the odd tangent bundle of the space $Z_6$. Quantizing this model yields a Dirac oscillator equation on the phase space whose solution space is a direct sum of two spinor spaces parametrized by holomorphic and antiholomorphic functions on the odd tangent bundle of $Z_6$. After expanding the general solution in Grassmann variables, we obtain components of the spinor field that are holomorphic and antiholomorphic functions from Bergman spaces on $Z_6$ with different weight functions. Thus, the supersymmetric model under consideration is exactly solvable, Lorentz covariant and unitary.