Chemical Wiring and Soldering toward All-Molecule Electronic Circuitry

Key to single-molecule electronics is connecting functional molecules to each other using conductive nanowires. This involves two issues: how to create conductive nanowires at designated positions, and how to ensure chemical bonding between the nanowires and functional molecules. Here, we present a...

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Veröffentlicht in:	Journal of the American Chemical Society 2011-06, Vol.133 (21), p.8227-8233
Hauptverfasser:	Okawa, Yuji, Mandal, Swapan K, Hu, Chunping, Tateyama, Yoshitaka, Goedecker, Stefan, Tsukamoto, Shigeru, Hasegawa, Tsuyoshi, Gimzewski, James K, Aono, Masakazu
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container_issue	21
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container_title	Journal of the American Chemical Society
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creator	Okawa, Yuji Mandal, Swapan K Hu, Chunping Tateyama, Yoshitaka Goedecker, Stefan Tsukamoto, Shigeru Hasegawa, Tsuyoshi Gimzewski, James K Aono, Masakazu
description	Key to single-molecule electronics is connecting functional molecules to each other using conductive nanowires. This involves two issues: how to create conductive nanowires at designated positions, and how to ensure chemical bonding between the nanowires and functional molecules. Here, we present a novel method that solves both issues. Relevant functional molecules are placed on a self-assembled monolayer of diacetylene compound. A probe tip of a scanning tunneling microscope is then positioned on the molecular row of the diacetylene compound to which the functional molecule is adsorbed, and a conductive polydiacetylene nanowire is fabricated by initiating chain polymerization by stimulation with the tip. Since the front edge of chain polymerization necessarily has a reactive chemical species, the created polymer nanowire forms chemical bonding with an encountered molecular element. We name this spontaneous reaction “chemical soldering”. First-principles theoretical calculations are used to investigate the structures and electronic properties of the connection. We demonstrate that two conductive polymer nanowires are connected to a single phthalocyanine molecule. A resonant tunneling diode formed by this method is discussed.
doi_str_mv	10.1021/ja111673x
format	Article
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title	Chemical Wiring and Soldering toward All-Molecule Electronic Circuitry
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