Entanglement, Trace Anomaly and Confinement in QCD

Abstract

We formulate confinement in QCD as an entropic surface phenomenon. Quark and gluon quantum information is localized on a transverse entangling two-sphere of radius REE; at this radius the QCD vacuum -- partitioned by a hadron into interior and exterior regions -- reaches its maximal entanglement entropy. Lattice-QCD determinations of the scalar (trace) gravitational form factors fix both REE and the transverse trace-anomaly density h(REE), yielding a parameter-free slope ch = 8π2 REE2\,h(REE) and a mechanical entropy SEE(y)=ch\,y that grows linearly with rapidity y. The entropy gradient ∂R SEE changes sign at REE: it pushes colored degrees of freedom outward for r<REE and pulls them inward for r>REE, thereby localizing them on the codimension-2 entangling two-sphere = S2REE (which, in the infinite-momentum frame, projects onto the transverse plane), the 'information wall'. This provides a high-energy (large-y) entropic confinement diagnostic that complements -- rather than replaces -- Wilson's area-law criterion, which probes long-distance dynamics near the rest frame (y 0). Imposing unitarity on an entropic ansatz for the amplitude yields σ(s) yδ. World data favor δ=2 for elastic pp\,(p p) scattering and heavy-quark photoproduction, whereas φ photoproduction favors a softer δ=0.387. All extracted cross sections remain well below the Froissart--Martin bound. These results provide a confinement criterion quantified directly from non-perturbative QCD inputs, unifying the trace anomaly, entanglement entropy, and high-energy scattering within a single quantitative framework.