A basis-free, octonionic criterion for Weyl points in solids

Abstract: Conventional diagnostics of Weyl points -- Berry flux on small spheres and $k \cdot p$ linearization -- are topologically sound but depend on user choices (sphere center and radius, gauge smoothing, charting, and local frame transport) that introduce algorithmic arbitrariness in first-principles workflows. We propose a \emph{local, basis-free} criterion built from the octonionic structure on $\mathbb{R}^7$. From a smooth two-band projector we construct a unit octonion field and its octonionic connection; contracting three directional derivatives with the $\mathrm{G}_2$--invariant three-form yields a pseudoscalar density whose sign equals the Weyl chirality. A vanishing octonionic associator at leading order certifies that the local problem closes inside an associative (quaternionic) three-plane, while a nonzero density identifies a Weyl point. The construction is invariant under $\mathrm{SU}(2)$ gauge changes of the two-band subspace and under $\mathrm{G}_2$ rotations of its completion, and it eliminates enclosing surfaces and gauge-seam choices. In the linear regime we prove equivalence with the conventional diagnostics (Chern charge on a small sphere and $\mathrm{sgn}\det v$). We outline a practical algorithm compatible with Wannier tight-binding Hamiltonians and provide self-consistency checks based on stencil refinement and the associator norm. The \emph{octonionic Weyl point criterion} streamlines chirality assignment in high-throughput searches and offers an intrinsic warning signal in the presence of band entanglement or proximity to multi-fold touchings.