Quantum Bootstrap Approach to a Non-Relativistic Potential for Quarkonium systems

Abstract

The quantum bootstrap method is applied to determine the bound-state spectrum of Quarkonium systems using a non-relativistic potential approximation. The method translates the Schr\"odinger equation into a set of algebraic recursion relations for radial moments rm , which are constrained by the positive semidefiniteness of their corresponding Hankel matrices. The numerical implementation is first validated by calculating the 1S and 1P mass centroids for both charmonium (cc) and bottomonium (bb) systems, finding deviations of less than 0.5\% from experimental data from the Particle Data Group (PDG). This analysis is then extended to the hypothetical toponium (tt) system, predicting a 1S ground state mass of M ≈ 344.3 GeV. This theoretical mass is in agreement with the energy of the recently observed resonance-like enhancement in the tt cross-section by the ATLAS and CMS collaborations. This result provides theoretical support for the interpretation of this experimental phenomenon as the formation of a quasi-bound toponium state and highlights the predictive power of the non-relativistic potential approach for systems of two massive quarks.