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Abstract
Graphene nanoribbons (GNRs) and their derivatives attract growing attention due to their excellent electronic and magnetic properties as well as the fine-tuning of such properties that can be obtained by heteroatom substitution and/or edge morphology modification. Here, we introduce graphene nanoribbon derivatives—organometallic hybrids with gold atoms incorporated between the carbon skeleton and side Cl atoms. We show that narrow chlorinated 5-AGNROHs (armchair graphene nanoribbon organometallic hybrids) can be fabricated by on-surface polymerization with omission of the cyclodehydrogenation reaction by a proper choice of tailored molecular precursors. Finally, we describe a route to exchange chlorine atoms connected through gold atoms to the carbon skeleton by hydrogen atom treatment. This is achieved directly on the surface, resulting in perfect unsubstituted hydrogen-terminated GNRs. This will be beneficial in the molecule on-surface processing when the preparation of final unsubstituted hydrocarbon structure is desired.
Highlights
Graphene nanoribbons (GNRs) and their derivatives attract growing attention due to their excellent electronic and magnetic properties as well as the finetuning of such properties that can be obtained by heteroatom substitution and/or edge morphology modification
Graphene nanoribbons (GNRs) and nanographenes are regarded as promising candidates for the generation of nano- and optoelectronic applications.[1−6] While this new class of materials retains outstanding transport properties characteristic of graphene, the lateral confinement of armchair graphene nanoribbons (AGNRs) opens a band gap
Most often the on-surface synthesis of GNRs proceeds in two sequential steps: (a) the halogen-equipped molecular precursors are activated thermally by carbon−halogen bond cleavage followed by Ullmann coupling to form polymers[27,28] and (b) at higher temperature the oligomers are transformed into GNR by surface-assisted cyclodehydrogenation.[29]
Summary
Graphene nanoribbons (GNRs) and their derivatives attract growing attention due to their excellent electronic and magnetic properties as well as the finetuning of such properties that can be obtained by heteroatom substitution and/or edge morphology modification.
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