Achieving near-intrinsic electrical properties of graphene nanoribbons via AgTe monolayer intercalation

Embedding a dielectric layer between as-synthesized graphene nanoribbons (GNRs) and metal surfaces represents a powerful strategy to achieve electronic decoupling, thereby enabling the extraction of these ribbons’ intrinsic electrical properties. Although several reports have documented dielectric intercalation between GNRs and metal substrates, studies on Ag(111) substrates are limited. Here, we demonstrate a semiconducting AgTe monolayer intercalation method to achieve electronic decoupling between as-synthesized GNRs and an Ag(111) substrate. Using low-temperature scanning tunneling microscopy, we directly observed the AgTe intercalation process at the GNR/Ag(111) interface. By combining scanning tunneling spectroscopy and density functional theory calculations, we elucidate the critical role of AgTe monolayer intercalation in reducing the interaction between as-synthesized GNRs and the Ag(111) substrate and observe the near-intrinsic electrical properties of the GNRs. Our findings offer a practical and effective strategy for intercalating AgTe monolayers between carbon-based nanomaterials and Ag(111) substrates, facilitating the unambiguous characterization of the near-intrinsic electronic properties of these materials.