Tuning the Fermi Level of Graphene by Two-Dimensional Metals for Raman Detection of Molecules

Abstract: Graphene-enhanced Raman scattering (GERS) offers great opportunities to achieve optical sensing with a high uniformity and superior molecular selectivity. The GERS mechanism relies on charge transfer between molecules and graphene, which is difficult to manipulate by varying the band alignment between graphene and the molecules. In this work, we synthesized a few atomic layers of metal termed two-dimensional (2D) metal to precisely and deterministically modify the graphene Fermi level. Using copper phthalocyan… Show more

“…Recently, graphene enhanced Raman spectroscopy (GERS) has received much attention due to its capabilities to characterize molecules, proteins, and biological samples pronouncedly, rendering itself a powerful candidate for potential applications in biosensors [34,35]. GERS involves the charge transfer between the graphene substrate and the target molecules, which might imply the possible applications of van Hove singularities of ABt-TTG in GERS.…”

G band enhancement in ABt-twisted trilayer graphene

“…Recently, graphene enhanced Raman spectroscopy (GERS) has received much attention due to its capabilities to characterize molecules, proteins, and biological samples pronouncedly, rendering itself a powerful candidate for potential applications in biosensors [34,35]. GERS involves the charge transfer between the graphene substrate and the target molecules, which might imply the possible applications of van Hove singularities of ABt-TTG in GERS.…”

G band enhancement in ABt-twisted trilayer graphene