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Graphene possesses many outstanding properties: it conducts heat and electricity, it is transparent, harder than diamond and extremely strong. But in order to use it to construct electronic switches, a material must not only be an outstanding conductor, it should also be switchable between ”on” and ”off” states. This requires the presence of a so-called bandgap, which enables semiconductors to be in an insulating state. The problem, however, is that the bandgap in graphene is extremely small. Empa researchers from the ”nanotech@surfaces” laboratory thus developed a method some time ago to synthesize a form of graphene with larger bandgaps by allowing ultra-narrow graphene nanoribbons to ”grow” via molecular self-assembly.
via Science Daily
Graphene possesses many outstanding properties: it conducts heat and electricity, it is transparent, harder than diamond and extremely strong. But in order to use it to construct electronic switches, a material must not only be an outstanding conductor, it should also be switchable between ”on” and ”off” states. This requires the presence of a so-called bandgap, which enables semiconductors to be in an insulating state. The problem, however, is that the bandgap in graphene is extremely small. Empa researchers from the ”nanotech@surfaces” laboratory thus developed a method some time ago to synthesize a form of graphene with larger bandgaps by allowing ultra-narrow graphene nanoribbons to ”grow” via molecular self-assembly.
via Science Daily
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