Energy gaps of atomically precise armchair graphene sidewall nanoribbons

Abstract

Graphene nanoribbons (GNRs) are one-dimensional (1D) structures that exhibit a rich variety of electronic properties1-17. Therefore, they are predicted to be the building blocks in next-generation nanoelectronic devices. Theoretically, it has been demonstrated that armchair GNRs can be divided into three families, i.e., Na = 3p, Na = 3p + 1, and Na = 3p + 2 (here Na is the number of dimer lines across the ribbon width and p is an integer), according to their electronic structures, and the energy gaps for the three families are quite different even with the same p1,3-6. However, a systematic experimental verification of this fundamental prediction is still lacking, owing to very limited atomic-level control of the width of the armchair GNRs investigated7,9,10,13,17. Here, we studied electronic structures of the armchair GNRs with atomically well-defined widths ranging from Na = 6 to Na = 26 by using scanning tunnelling microscope (STM). Our result demonstrated explicitly that all the studied armchair GNRs exhibit semiconducting gaps due to quantum confinement and, more importantly, the observed gaps as a function of Na are well grouped into the three categories, as predicted by density-functional theory calculations3. Such a result indicated that we can tune the electronic properties of the armchair GNRs dramatically by simply adding or cutting one carbon dimer line along the ribbon width.