Schwinger Model with a Dynamical Axion
Abstract
One of the major open puzzles in the Standard Model of particle physics is the strong CP problem: although Quantum Chromodynamics allows a CP-violating topological θ-term, experiments constrain its value to be extremely small. The Peccei--Quinn mechanism resolves this problem by promoting the θ-angle to a dynamical field-introducing the axion -- whose dynamics relax the effective angle θeff to a CP-conserving minimum. Here, we investigate the resulting axion physics in a Hamiltonian lattice gauge theory (LGT) by coupling a quantized axion field to the massive Schwinger model with a topological θ-term. Using infinite matrix product state techniques, we compute the ground-state properties of the resulting theory and demonstrate that the axion dynamically relaxes θeff to the minimum of the vacuum energy. Consequently, the ground-state energy becomes independent of θ, demonstrating the axion-mediated solution to the strong CP problem within a fully dynamical LGT. We further analyze CP restoration and extract the axion mass from the topological susceptibility and excitation spectrum. Our results provide a nonperturbative demonstration of axion dynamics in a quantum LGT amenable to investigation on modern quantum hardware.
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