ATLAS Shrugged: Resolving Experimental Tensions in Particle Physics Through Holographic Theory

Abstract

We present a unified information-theoretic analysis of experimental tensions observed in two distinct physical domains: the ATLAS experiment’s charged lepton flavor violation searches and the ALPHA-g antimatter gravity measurements. By applying the Quantum-Thermodynamic Entropy Partition (QTEP) frame work, we demonstrate that both experimental results reveal the same fundamental thermodynamic principles operating at different scales. Our analysis of ATLAS momentum distributions identifies transition patterns at precisely px(τ) = ±(γ/H)×(mZ/2) ≈ ±20 GeV, while angular distributions exhibit asymmetry ratios matching Scoh/|Sdecoh| ≈ 2.257. Similarly, the ALPHA-g experiment’s observation of antihydrogen falling at 0.75g±0.29g
is precisely explained through the same thermodynamic ratio and the universal 2/π scaling factor. We demonstrate that these seemingly unrelated phenomena—particle physics distributions and antimatter gravitational behavior—emerge from a common information-theoretic foundation, with antimatter fundamentally manifest ing as coherent entropy. The profound alignment between predicted transition points, observed asymmetries, and gravitational effects across vastly different energy scales provides compelling evidence for the universality of the holographic framework, offering a comprehensive resolution to experimental tensions without requiring modifications to the Standard Model or General Relativity.