Infrared fixed point of QCD, critical flavor number and triality automorphism of octonions

TL;DR

This paper proposes that the infrared fixed point structure of QCD is related to the triality automorphism of octonions, resolving discrepancies in the critical flavor number from different methods and connecting topological structures with lattice and experimental results.

Contribution

It introduces a novel topological interpretation of the infrared fixed point of QCD using octonion triality automorphism, unifying various theoretical and experimental findings.

Findings

Lattice simulations and experimental data suggest an IR fixed point with G2 topological structure.

The boundary conditions on S^3×R relate to quaternionic structures influencing the fixed point.

Proton form factors align with phenomenological dipole fits through Ward identity analysis.

Abstract

We show that the discrepancy on the critical flavor number of fermions $N_f^c$ for the appearance of the infrared fixed point based on the t'Hooft anomaly matching condition and derived from the Schr\"odinger functional method ($N_f^c\sim 9)$ and the experimental analysis of the JLab group using Bjorken sum rule and GDH sum rule, and our lattice simulation($N_f^c\sim 3$) could be resolved by assuming the topological structure of the infrared fixed point is not that of $U(1)^3$ but that of $G_2$ with triality automorphism of octonions which appear in the product of quaternions. The agreement of the infrared fixed point of the running coupling measured in lattice simulations with use of the quaternion real condition and the prediction of the BLM renormalization theory might be due to the boundary condition on $S^3\times R$ manifold of quaternion. The form factor of a proton measured via Ward identity through the difference of the inverse propagator at momentum p+q/2 and at p-q/2 agrees with the phenomenological dipole fit.