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Solution-processed, high-performance n-channel organic microwire transistors.


ABSTRACT: The development of solution-processable, high-performance n-channel organic semiconductors is crucial to realizing low-cost, all-organic complementary circuits. Single-crystalline organic semiconductor nano/microwires (NWs/MWs) have great potential as active materials in solution-formed high-performance transistors. However, the technology to integrate these elements into functional networks with controlled alignment and density lags far behind their inorganic counterparts. Here, we report a solution-processing approach to achieve high-performance air-stable n-channel organic transistors (the field-effect mobility (mu) up to 0.24 cm(2)/Vs for MW networks) comprising high mobility, solution-synthesized single-crystalline organic semiconducting MWs (mu as high as 1.4 cm(2)/Vs for individual MWs) and a filtration-and-transfer (FAT) alignment method. The FAT method enables facile control over both alignment and density of MWs. Our approach presents a route toward solution-processed, high-performance organic transistors and could be used for directed assembly of various functional organic and inorganic NWs/MWs.

SUBMITTER: Oh JH 

PROVIDER: S-EPMC2669358 | biostudies-literature | 2009 Apr

REPOSITORIES: biostudies-literature

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Solution-processed, high-performance n-channel organic microwire transistors.

Oh Joon Hak JH   Lee Hang Woo HW   Mannsfeld Stefan S   Stoltenberg Randall M RM   Jung Eric E   Jin Yong Wan YW   Kim Jong Min JM   Yoo Ji-Beom JB   Bao Zhenan Z  

Proceedings of the National Academy of Sciences of the United States of America 20090319 15


The development of solution-processable, high-performance n-channel organic semiconductors is crucial to realizing low-cost, all-organic complementary circuits. Single-crystalline organic semiconductor nano/microwires (NWs/MWs) have great potential as active materials in solution-formed high-performance transistors. However, the technology to integrate these elements into functional networks with controlled alignment and density lags far behind their inorganic counterparts. Here, we report a sol  ...[more]

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