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Graphene nanoribbons (GNRs) have gained significant attention in nanoelectronics due to their potential for precise tuning of electronic properties through variations in edge structure and ribbon width. However, the synthesis of GNRs with highly sought-after zigzag edges (ZGNRs), critical for spintronics and quantum information technologies, remains challenging. In this study, a design motif for synthesizing a novel class of GNRs termed edge-extended ZGNRs is presented. This motif enables the controlled incorporation of edge extensions along the zigzag edges at regular intervals. The synthesis of a specific GNR instance-a 3-zigzag-rows-wide ZGNR-with bisanthene units fused to the zigzag edges on alternating sides of the ribbon axis is successfully demonstrated. The resulting edge-extended 3-ZGNR is comprehensively characterized for its chemical structure and electronic properties using scanning probe techniques, complemented by density functional theory calculations. The design motif showcased here opens up new possibilities for synthesizing a diverse range of edge-extended ZGNRs, expanding the structural landscape of GNRs and facilitating the exploration of their structure-dependent electronic properties.|In this study, a new design motif is introduced to synthesize edge-extended zigzag graphene nanoribbons (ZGNRs). Using scanning probe techniques and density functional theory, the chemical structure and electronic characteristics of a 3-zigzag-row ZGNR instance are confirmed. This approach expands the range of possible ZGNRs, contributing to further understanding of structure-dependent electronic properties in GNRs.image
Johannes Schwenk, Donat Fabian Natterer
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Oleg Yazyev, Kristians Cernevics