2019
DOI: 10.1088/1361-648x/ab1680
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Lateral scaling and positioning effects of top-gate electrodes on single-molecule field-effect transistors

Abstract: Molecular electronics aims at integrating controllable molecular devices into circuits or machines to realize certain functions. According to device configuration, molecular field-effect transistors with top-gate electrodes have great advantages for integration. Nevertheless, from technical aspects, it is difficult to control lateral scale and position of a top-gate electrode precisely. Therefore, one problem arises in how lateral scaling and positioning effects of a top-gate electrode affect device performanc… Show more

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Cited by 2 publications
(1 citation statement)
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“…[1,2] Since the first rectifier was proposed by Aviram and Ratner, [3] functional single-molecule junctions have been fabricated by investigating the electron transport properties for various applications, such as molecular rectifiers, [4][5][6] molecular conducting wires, [7][8][9] molecular switches, [10][11][12] and molecular transistors. [13][14][15] In this context, understanding and controlling the electron transfer process based on the core functional molecules between electrodes is essential for developing the single-molecule junctions. The single-molecule junction conductance has been theoretically and experimentally verified to primarily depend on the molecular geometry and molecule-electrode interface, which includes factors like anchoring groups, interfacial geometry, and electrode characteristics.…”
Section: Introductionmentioning
confidence: 99%
“…[1,2] Since the first rectifier was proposed by Aviram and Ratner, [3] functional single-molecule junctions have been fabricated by investigating the electron transport properties for various applications, such as molecular rectifiers, [4][5][6] molecular conducting wires, [7][8][9] molecular switches, [10][11][12] and molecular transistors. [13][14][15] In this context, understanding and controlling the electron transfer process based on the core functional molecules between electrodes is essential for developing the single-molecule junctions. The single-molecule junction conductance has been theoretically and experimentally verified to primarily depend on the molecular geometry and molecule-electrode interface, which includes factors like anchoring groups, interfacial geometry, and electrode characteristics.…”
Section: Introductionmentioning
confidence: 99%