A Finite-Lattice Model from a Reciprocal Cost Action: Spectral and Reflection-Positivity Properties

Abstract

We study the finite-lattice statistical-mechanical model whose nearest-neighbor bond potential is the reciprocal cost J(e)=-1, selected by the d'Alembert functional equation under the stated regularity and calibration assumptions. The structural inputs are stated explicitly; once they are fixed, the analysis is rigorous mathematics about the bond action V(Δϕ)=(Δϕ)-1 on finite boxes in Z3× Z/8 Z. Our main result pairs a negative and a positive statement about reflection positivity. For the continuous noncompact model the natural temporal kernel K(u)=[-( u-1)] fails the Bochner positive-definiteness test: an interval-certified quadrature gives K(3)<0. Thus the standard Bochner route to Osterwalder-Schrader reflection positivity is obstructed. For a finite-alphabet variant, with field values restricted to a finite symmetric set Φ=v0\-N,…,N\, reflection positivity holds whenever the finite crossing-bond Toeplitz matrix (KΦ(v0,N))a,b:=K(b-a), a,b∈Φ, is positive semidefinite. For v0∈\1.2,1.5,2.5\, this is discharged by a rigorous diagonal-dominance certificate uniform in N, and the associated one-step transfer operator is then positive and self-adjoint in an explicit reflection-positivity inner product. These finite-volume results do not provide a continuum Wightman theory, Osterwalder-Schrader reconstruction, LSZ scattering, or a continuum mass gap.