Abstract
Catalytic unzipping of single-walled carbon nanotubes (SWCNTs) has been experimentally shown to be a viable method to produce graphene nanoribbons (GNRs) with clean and smooth edges for advanced applications, while topological defects (TDs) are inevitably presented in mass produced CNTs (especially the tube end/cap), which may affect the catalytic unzipping. Herein, we theoretically investigate the roles of TDs on the catalytic unzipping of SWCNTs by a single Fe atom in the H2 environment. Our computation shows that the threshold reaction barriers to the catalytic SWCNT unzipping can be notably reduced by ∼20%-40%, resulting from weakened and elongated local C-C bonds associated with TDs. The curvature energy of a SWCNT released during the unzipping can support the continuous unzipping and enable the chirality- and diameter-dependent unzipping. The important roles of H2 are also identified. The suggested tear-from-end-defect mechanism can markedly improve the controllability of the catalytic unzipping of SWCNTs.
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