Threshold Resonances, Critical Couplings, and Eigenvalue Bounds for Two-Particle Operators on Z3

Abstract

We study a family of lattice Schr\"odinger operators Hμ1μ2(K) describing two identical bosons on the three-dimensional cubic lattice Z3, where K ∈ T3 is the quasi-momentum, and μ1, μ2 ∈ R are coupling constants corresponding to on-site and nearest-neighbour interactions, respectively. We show that the Hilbert space L2,e(T3) decomposes into three mutually orthogonal subspaces, each invariant under Hμ1μ2(0). A detailed spectral analysis of the restriction of Hμ1μ2(0) to one of these subspaces reveals two smooth critical curves in the (μ1, μ2)-plane, separating regions where the number of eigenvalues below the essential spectrum remains constant. For the restrictions to the other two subspaces, we identify a critical point on the μ2-axis that partitions it into intervals with a constant number of eigenvalues below the essential spectrum. Analogously, two additional critical curves and one critical point determine regions and intervals where the number of eigenvalues above the essential spectrum is constant. In particular, for suitable parameter values, Hμ1μ2(0) may possess up to three bound states located either below or above the essential spectrum, with numbers (α,β) satisfying α + β < 3 or (α,β) ∈ \(3,0),(0,3)\. Here, by eigenvalue bounds we mean both the possible locations of eigenvalues outside the essential spectrum and the maximum number of such eigenvalues for given coupling parameters. Finally, we extend the analysis to arbitrary quasi-momentum K ∈ T3, obtaining general lower bounds for the number of eigenvalues of Hμ1μ2(K).

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