Geometric Characterization of Anisotropic Correlations via Mutual Information Tomography

Abstract

Characterizing anisotropic correlations in quantum and statistical systems requires a coordinate-invariant framework. We introduce a geometric map based on the local informational line element, calibrated by the Euclidean benchmark scale Cvac: ds2 = Cvac/I(x,x+ε). We prove that this map yields a smooth Riemannian structure gij if and only if the short-distance mutual information (MI) follows the anisotropic inverse-quadratic law (local exponent Xloc=2). A key insight is that anisotropy is necessary to activate tensor geometry; isotropic MI forces conformal flatness gij δij, suppressing shear degrees of freedom. We employ a parameterization-invariant unimodular split gij = V2/Dγij, which rigorously separates local density fluctuations (volume V) from directional anisotropy (shape/shear γij). We introduce ``MI Tomography,'' an operational protocol to reconstruct these geometric components from finite directional measurements. The protocol is validated using the equal-time ground state of an anisotropic 2D quantum harmonic lattice (massless relativistic scalar) on a torus, where the reconstructed shape tensor γij quantitatively recovers the physical coupling anisotropy. We work strictly in the local, fixed-coarse-graining Xloc=2 branch; the line element is used solely to extract the local kinematic structure (the local metric tensor), deferring global distance claims.

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