0000000000599921

AUTHOR

Thorsten Prechtl

showing 2 related works from this author

Charge transport mechanism in networks of armchair graphene nanoribbons

2020

In graphene nanoribbons (GNRs), the lateral confinement of charge carriers opens a band gap, the key feature to enable novel graphene-based electronics. Successful synthesis of GNRs has triggered efforts to realize field-effect transistors (FETs) based on single ribbons. Despite great progress, reliable and reproducible fabrication of single-ribbon FETs is still a challenge that impedes applications and the understanding of the charge transport. Here, we present reproducible fabrication of armchair GNR-FETs based on a network of nanoribbons and analyze the charge transport mechanism using nine-atom wide and, in particular, five-atom-wide GNRs with unprecedented conductivity. We show formati…

Materials scienceBand gap530 Physicslcsh:MedicineFOS: Physical sciences02 engineering and technology010402 general chemistry01 natural sciencesArticlelaw.inventionlawMesoscale and Nanoscale Physics (cond-mat.mes-hall)lcsh:ScienceCondensed-matter physicsOhmic contactQuantum tunnellingMultidisciplinaryCondensed Matter - Mesoscale and Nanoscale Physicsbusiness.industryGraphenelcsh:RTransistorCharge (physics)021001 nanoscience & nanotechnology530 PhysikMaterials science0104 chemical sciencesOptoelectronicslcsh:QCharge carrier0210 nano-technologybusinessGraphene nanoribbons
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Lateral Fusion of Chemical Vapor Deposited N = 5 Armchair Graphene Nanoribbons

2017

Bottom-up synthesis of low-bandgap graphene nanoribbons with various widths is of great importance for their applications in electronic and optoelectronic devices. Here we demonstrate a synthesis of N = 5 armchair graphene nanoribbons (5-AGNRs) and their lateral fusion into wider AGNRs, by a chemical vapor deposition method. The efficient formation of 10- and 15- AGNRs is revealed by a combination of different spectroscopic methods, including Raman and UV−visnear-infrared spectroscopy as well as by scanning tunneling microscopy. The degree of fusion and thus the optical and electronic properties of the resulting GNRs can be controlled by the annealing temperature, providing GNR films with o…

Annealing (metallurgy)Nanotechnology02 engineering and technologyChemical vapor deposition010402 general chemistryOptoelectronic devicesSpectroscopic analysisCatalysis; Chemistry (all); Biochemistry; Colloid and Surface Chemistry01 natural sciencesBiochemistryCatalysislaw.inventionsymbols.namesakeColloid and Surface ChemistrylawChemical vapor depositionSpectroscopyScanning tunneling microscopyElectronic propertiesFusionChemistryCommunicationChemistry (all)General Chemistry021001 nanoscience & nanotechnologyVapor deposition0104 chemical sciencesElectronic propertiessymbolsScanning tunneling microscopeGraphene0210 nano-technologyRaman spectroscopyGraphene nanoribbonsJournal of the American Chemical Society
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