Contact Effects on Thermoelectric Properties of Textured Graphene Nanoribbons

David M.T. Kuo, Yia Chung Chang

Research output: Contribution to journalArticlepeer-review

11 Scopus citations

Abstract

The transport and thermoelectric properties of finite textured graphene nanoribbons (t-GNRs) connected to electrodes with various coupling strengths are theoretically studied in the framework of the tight-binding model and Green’s function approach. Due to quantum constriction induced by the indented edges, such t-GNRs behave as serially coupled graphene quantum dots (SGQDs). These types of SGQDs can be formed by tailoring zigzag GNRs (ZGNRs) or armchair GNRs (AGNRs). Their bandwidths and gaps can be engineered by varying the size of the quantum dot and the neck width at indented edges. Effects of defects and junction contact on the electrical conductance, Seebeck coefficient, and electron thermal conductance of t-GNRs are calculated. When a defect occurs in the interior site of textured ZGNRs (t-ZGNRs), the maximum power factor within the central gap or near the band edges is found to be insensitive to the defect scattering. Furthermore, we found that SGQDs formed by t-ZGNRs have significantly better electrical power outputs than those of textured ANGRs due to the improved functional shape of the transmission coefficient in t-ZGNRs. With a proper design of contact, the maximum power factor (figure of merit) of t-ZGNRs could reach (Formula presented.) ((Formula presented.)) of the theoretical limit.

Original languageEnglish
Article number3357
JournalNanomaterials
Volume12
Issue number19
DOIs
StatePublished - Oct 2022

Keywords

  • edge states
  • junction contact
  • square-form transmission curve
  • textured graphene nanoribbons
  • thermoelectric properties
  • topological nature

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