High-chirality Weyl nodes in hexagonal ReO$_3$

The emergence of two-band nodal points (i.e. Weyl nodes) in gapless topological phases only requires translational symmetry, however, their necessary existence in the electronic band structure of materials can be deduced when additional crystalline symmetries are present. In particular, rotation symmetries have been known to be able to protect Weyl nodes of high chirality. In this work, we identify ReO$_3$ as an ideal high-chirality Weyl semimetal in which hexagonal screw symmetry plays a crucial role. To show this, we revisit in detail the algebraic determination of the chirality of Weyl nodes from the spinful irreducible representations of occupied bands, and combine it with the complementary $C_{2}T$-symmetry-protected patch Euler class that indicates the pinning of the Weyl nodes on $C_{2}T$-invariant planes. Supporting our findings with first-principles calculations, we furthermore reveal very clear Fermi arc signatures of the high-chirality Weyl nodes at the Fermi level and for different surface orientations. We finally consider the effect of strain upon which the reconfiguration of Weyl nodes further unveils their Chern (i.e. high chirality) and Euler (i.e. symmetry-plane pinning) topological nature.