$h/e$ Oscillations in Interlayer Transport of Delafossites

Transport of electrons in a metal is usually well captured by their particle-like aspects, while their wavelike nature is commonly unobservable. Microstructures can be carefully designed to shield the quantum phase of the electrons from decoherence due to external perturbations, for example, mesoscopic metal rings resembling interferometers. Here we report a new type of phase coherent oscillation of the out-of-plane magnetoresistance in the layered delafossites PdCoO$_2$ and PtCoO$_2$. The oscillation period is equivalent to that determined by the magnetic flux quantum, $h/e$, threading an area defined by the atomic interlayer separation and the sample width. The phase of the electron wave function in these crystals appears remarkably robust over macroscopic length scales exceeding 5$\mu$m and persisting up to elevated temperatures of 60K. While the microscopic origin of this effect remains to be clarified and challenges our understanding of interlayer transport in ultra-pure metals, the results suggest the feasibility of a novel class of magnetic field sensors of unprecedented atomic-scale spatial resolution.