Real-Analyticity of the Density of States for Random Schrödinger operators with Point Interactions

Abstract: We prove real-analyticity of the density of states (DOS) for random Schr\"odinger operators with lattice-supported point interactions in $\mathbb{R}^d$ ($d=1,2,3$) in the small-hopping regime. In the attractive case, Krein's resolvent formula reduces the problem to a lattice model, where a random-walk expansion and disorder averaging lead to single-site integrals with holomorphic single-site density $g$. Contour deformation in the coupling-constant plane under a uniform pole-gap condition ensures convergence of the averaged resolvent in a complex neighborhood of a negative-energy interval. This yields analyticity of the DOS. The method also applies to multi-point correlation functions, such as those in the Kubo--Greenwood formula.