CUED Publications database

Self-Assembled Molecular Nanowires for High-Performance Organic Transistors

Fleet, LR and Stott, J and Villis, B and Din, S and Serri, M and Aeppli, G and Heutz, S and Nathan, A (2017) Self-Assembled Molecular Nanowires for High-Performance Organic Transistors. ACS Applied Materials and Interfaces, 9. pp. 20686-20695. ISSN 1944-8244

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While organic semiconductors provide tantalizing possibilities for low-cost, light-weight, flexible electronic devices, their current use in transistors - the fundamental building block - is rather limited as their speed and reliability are not competitive with those of their inorganic counterparts and are simply too poor for many practical applications. Through self-assembly, highly ordered nanostructures can be prepared that have more competitive transport characteristics; however, no simple, scalable method has been discovered that can produce devices on the basis of such nanostructures. Here, we show how transistors of self-assembled molecular nanowires can be fabricated using a scalable, gradient sublimation technique, which have dramatically improved characteristics compared to those of their thin-film counterparts, both in terms of performance and stability. Nanowire devices based on copper phthalocyanine have been fabricated with threshold voltages as low as â2.1 V, high on/off ratios of 10 , small subthreshold swings of 0.9 V/decade, and mobilities of 0.6 cm /V s, and lower trap energies as deduced from temperature-dependent properties, in line with leading organic semiconductors involving more complex fabrication. High-performance transistors manufactured using our scalable deposition technique, compatible with flexible substrates, could enable integrated all-organic chips implementing conventional as well as neuromorphic computation and combining sensors, logic, data storage, drivers, and displays. 5 2

Item Type: Article
Uncontrolled Keywords: image analysis mobility nanowire transistor neuromorphic computing organic electronics phthalocyanine random networks stability temperature dependence
Divisions: Div B > Solid State Electronics and Nanoscale Science
Depositing User: Unnamed user with email
Date Deposited: 17 Jul 2017 19:05
Last Modified: 15 Apr 2021 02:29
DOI: 10.1021/acsami.7b01449