Spectral statistics and energy-gap scaling in k-local spin Hamiltonians
Abstract
We investigate the spectral properties of all-to-all interacting spin Hamiltonians acting on exactly k spins, whose coupling coefficients are drawn from a normal distribution with mean μ and variance σ2. For μ = 0, we demonstrate that the random matrix ensemble -- Gaussian Orthogonal Ensemble (GOE), Gaussian Unitary Ensemble (GUE), or Gaussian Symplectic Ensemble (GSE) -- is determined by the parity of system size L and locality k, following standard time-reversal symmetry classification. For couplings with a nonzero mean, we map the Hamiltonians to deformed random matrix ensembles and analyze conditions for an energy gap between the ground state and the first excited state. For μ < 0, we find two distinct regimes: for k L, the gap closes at critical disorder σc ≈ |μ|. Near this transition the energy gap exhibits universal quadratic scaling /L (σ - σc)2. When k L, σc scales with |μ|, but lacks a sharp transition. Our work introduces a semi-solvable model that captures universal features of random-matrix statistics, and spectral gap formation, providing a foundation for systematic extensions to more general many-body systems.
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