Optical imaging of spontaneous electric polarizations in tetralayer graphene (2504.06874v1)

Abstract: The recent discovery of sliding ferroelectricity has sparked intense interests in studying interfacial polarizations in two-dimensional (2D) van der Waals materials. However, akin to the conventional ferroelectrics, the studies have predominantly reported semiconducting and/or insulating moir\'e systems and binary compounds. Spontaneous electric polarizations in elemental metallic phases remain scarcity. Here, we report the first optical imaging of intrinsic out-of-plane electric polarizations and domain wall (DW) sliding dynamics in tetralayer graphene, a 2D conductive layer composed entirely of carbon. Using scanning near-field optical microscopy (SNOM), we directly visualize adjacent ABAC and ABCB stacking orders with intrinsic and opposite electric polarizations. Our gate-dependent SNOM measurements reveal distinct optical response that systematically changes upon carrier doping and unconventional interplay between DW sliding and electric polarizations, which are supported by density functional theory (DFT) calculations. Independent corroboration through Kelvin probe force microscopy (KPFM) and Raman spectroscopy confirms the polar nature and their polarization directions. Furthermore, reversible mechanical switching of polar states via atomic force microscopy (AFM) tip manipulation is also demonstrated. Our work establishes SNOM as a critical tool for probing sliding ferroelectricity in conductive 2D layers, opening avenues for exploring multiferroic behaviors and nonvolatile memory applications in atomically thin metals at room temperature.