Probing Proton Structure via Physics-Guided Neural Networks in Holographic QCD

Abstract

Describing the proton structure function F2 in the non-perturbative and transition regimes of quantum chromodynamics (QCD) remains a significant theoretical challenge. In this work, we introduce a Physics-Guided Neural Network (PGNN) that integrates Holographic QCD with deep learning. By embedding the five-dimensional AdS5 Dirac equation and the string diffusion kernel directly into the computational graph, the network is strictly constrained to the physical proton mass (Mp 0.938 GeV). Applying this framework to high-precision SLAC deep inelastic scattering data yields a global fit of 2/d.o.f. 0.91. Rather than relying on predetermined empirical forms, the network dynamically extracts the transition between the s-channel bulk fermion mechanism (hadronic resonance excitations) and the t-channel holographic Pomeron exchange (diffractive background), identifying a kinematic crossover near x ≈ 0.19. Furthermore, the optimization naturally recovers a Pomeron intercept of α0 ≈ 1.0786 and generates higher-twist scale-breaking effects through the evolution of resonance mass spectra. This demonstrates that embedding analytical differential equations into neural networks provides an interpretable, data-driven approach for phenomenological studies of strongly coupled systems.