Visualizing the response of Weyl semimetals to Coulomb and magnetic perturbations

Weyl semimetals are a new class of topological materials which led to the emergence of Weyl physics in condensed matter. Beyond the fundamental interest of their topological aspects, they have been reported to host remarkable properties which arise from the complicated interplay of their multi-band structure, the lack of inversion symmetry, and strong spin-orbit coupling. While photoemission successfully identified Weyl surface states with unique Fermi arcs, their fundamental microscopic properties such as scattering mechanisms, persistence of spin-coherence, and the reaction to external perturbations have not been widely investigated so far. Here, we use TaAs as a prototypical system to address these important aspects at the atomic scale by scanning tunneling microscopy and spectroscopy. We deliberately introduce external adatoms to test the response of this class of materials to well-defined Coulomb and magnetic perturbations. We demonstrate that, contrary to topological insulators, they are effectively screened in Weyl semimetals. By quasiparticle interference mapping, we detect the emergence of a rich scattering scenario. The presence of external adatoms acting as additional scattering centers significantly enhances the signal-to-noise ratio. This allows to visualize previously undetected short-range scattering mechanisms which allow testing theoretical predictions on the potential impact of Fermi arcs. Our analysis demonstrates that intra- as well as inter-Fermi arc scattering events are strongly suppressed. Additionally, we show that the existence of large parallel segments of spin-split trivial states facing each other makes possible, through scattering, to revert both the propagation direction while simultaneously flipping the spin state, strongly limiting its coherence.