2023
DOI: 10.1039/d3nr00632h
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Nanoscale chemical patterning of graphite at different length scales

Abstract: A combination of covalent and non-covalent strategy was used to achieve nanoscale chemical patterning of graphite at multiple length scales: few hundred nanometer circular patterns interspersed with sub-10 nm linear arrays.

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Cited by 3 publications
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“…Currently, the research is focused on the approaches to control not only the chemistry and surface density of functional grafts, but also their spatial order. Bottom-up strategies for patterned covalent functionalization rely on the design of special radical precursors, 9 molecular building blocks 10 or larger aggregates 11 capable of on-surface self-assembly. Upon activation of aryl radicals, such on-surface adsorbates lead to patterned grafting that matches the symmetry and dimensions of the initial self-assembly, albeit with limitations that arbitrary shapes are not possible, and that for each new pattern one has to design and optimize another new ‘molecular assembly-grafting’ system.…”
mentioning
confidence: 99%
“…Currently, the research is focused on the approaches to control not only the chemistry and surface density of functional grafts, but also their spatial order. Bottom-up strategies for patterned covalent functionalization rely on the design of special radical precursors, 9 molecular building blocks 10 or larger aggregates 11 capable of on-surface self-assembly. Upon activation of aryl radicals, such on-surface adsorbates lead to patterned grafting that matches the symmetry and dimensions of the initial self-assembly, albeit with limitations that arbitrary shapes are not possible, and that for each new pattern one has to design and optimize another new ‘molecular assembly-grafting’ system.…”
mentioning
confidence: 99%