Abstract
We report on a study of the supersymmetric anharmonic oscillator computed using a euclidean lattice path integral. Our numerical work utilizes a Fourier accelerated hybrid Monte Carlo scheme to sample the path integral. Using this we are able to measure massgaps and check Ward identities to a precision of better than one percent. We work with a non-standard lattice action which we show has an exact supersymmetry for arbitrary lattice spacing in the limit of zero interaction coupling. For the interacting model we show that supersymmetry is restored in the continuum limit without fine tuning. This is contrasted with the situation in which a `standard' lattice action is employed. In this case supersymmetry is not restored even in the limit of zero lattice spacing. Finally, we show how a minor modification of our action leads to an exact, local lattice supersymmetry even in the presence of interaction.
Highlights
Supersymmetry is thought to be a crucial ingredient in any theory which attempts to unify the separate interactions contained in the standard model of particle physics
Supersymmetry being a spacetime symmetry is explicitly broken by the discretization procedure and it is highly non-trivial problem to show that it is recovered in the continuum limit. One manifestation of this problem is the usual doubling problem of lattice fermions - the naive fermion action in D dimensions possesses not one but 2D continuum-like modes. These extra modes persist in the continuum limit and yield an immediate conflict with supersymmetry requiring as it does an equality between boson and fermion degrees of freedom
We have performed a numerical study of the lattice supersymmetric anharmonic oscillator computed using path integrals
Summary
Follow this and additional works at: https://surface.syr.edu/phy Part of the Physics Commons. Recommended Citation Catterall, Simon and Gregory, Eric B., "A Lattice Path Integral for Supersymmetric Quantum Mechanics" (2000). Simon Catterall∗ and Eric Gregory† ∗ Physics Department, Syracuse University, Syracuse, NY 13244 † Department of Physics, Zhongshan University, Guangzhou 510275, China
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