Multiple heteroatom substitution to graphene nanoribbon | Zendy

Shigeki Kawai | Zendy; Soichiro Nakatsuka | Zendy; Takuji Hatakeyama | Zendy; Rémy Pawlak | Zendy; Tobias Meier | Zendy; John Tracey | Zendy; Ernst Meyer | Zendy; Adam S. Foster | Zendy

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Multiple heteroatom substitution to graphene nanoribbon

Author(s) -

Shigeki Kawai,

Soichiro Nakatsuka,

Takuji Hatakeyama,

Rémy Pawlak,

Tobias Meier,

John Tracey,

Ernst Meyer,

Adam S. Foster

Publication year - 2018

Publication title -

science advances

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 5.928

H-Index - 146

ISSN - 2375-2548

DOI - 10.1126/sciadv.aar7181

Subject(s) - heteroatom , graphene , substitution (logic) , atomic force microscopy , materials science , nanotechnology , resolution (logic) , crystallography , chemical physics , chemistry , computer science , ring (chemistry) , organic chemistry , artificial intelligence , programming language

Substituting heteroatoms into nanostructured graphene elements, such as graphene nanoribbons, offers the possibility for atomic engineering of electronic properties. To characterize these substitutions, functionalized atomic force microscopy (AFM)-a tool to directly resolve chemical structures-is one of the most promising tools, yet the chemical analysis of heteroatoms has been rarely performed. We synthesized multiple heteroatom-substituted graphene nanoribbons and showed that AFM can directly resolve elemental differences and can be correlated to the van der Waals radii, as well as the modulated local electron density caused by the substitution. This elemental-sensitive measurement takes an important step in the analysis of functionalized two-dimensional carbon materials.

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