Toward High-Output Organic Vertical Field Effect Transistors: Key Design Parameters

The performance of C60‐based organic vertical field‐effect transistors (VFETs) is investigated as a function of key geometrical parameters to attain a better understanding of their operation mechanism and eventually to enhance their output current for maximal driving capability. To this end, a 2D de...

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Published in:Advanced functional materials 2016-10, Vol.26 (38), p.6888-6895
Main Authors: Kwon, Hyukyun, Kim, Mincheol, Cho, Hyunsu, Moon, Hanul, Lee, Jongjin, Yoo, Seunghyup
Format: Article
Language:English
Subjects:
Buckminsterfullerene
C60
Channels
device simulation
Drains
Electrodes
Field effect transistors
organic electronics
organic field-effect transistors
Parameters
Semiconductor devices
Thickness
vertical field-effect transistors
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cited_by cdi_FETCH-LOGICAL-c3606-d6a3658abc0ce44ab3289f4540eda8e990ba18dba74f252e98f2f7a630ef160d3
cites cdi_FETCH-LOGICAL-c3606-d6a3658abc0ce44ab3289f4540eda8e990ba18dba74f252e98f2f7a630ef160d3
container_end_page 6895
container_issue 38
container_start_page 6888
container_title Advanced functional materials
container_volume 26
creator Kwon, Hyukyun
Kim, Mincheol
Cho, Hyunsu
Moon, Hanul
Lee, Jongjin
Yoo, Seunghyup
description The performance of C60‐based organic vertical field‐effect transistors (VFETs) is investigated as a function of key geometrical parameters to attain a better understanding of their operation mechanism and eventually to enhance their output current for maximal driving capability. To this end, a 2D device simulation is performed and compared with experimental results. The results reveal that the output current scales mostly with the width of its drain electrode, which is in essence equivalent to the channel width in conventional lateral‐channel transistors, but that of the source electrode and the thickness of C60 layers underneath the source electrode also play subtle but important roles mainly due to the source contact‐limited behavior of the organic VFETs under study. With design strategies acquired from this study, a VFET with an on/off ratio of 5.5 × 105 and on‐current corresponding to a channel length of near 1 μm in a conventional lateral‐channel organic field‐effect transistor (FET) is demonstrated, while the drain width of the VFET and the channel width of the lateral‐channel organic FET are the same. The operation mechanism and performance of organic vertical field effect transistors (VFETs) have been investigated. Several key factors are identified such as source/drain electrode widths, source contact resistance, and bottom active layer thickness. With the key parameters, the proposed VFET shows greater performance than conventional organic field‐effect transistors with lateral channel in terms of driving capability.
doi_str_mv 10.1002/adfm.201601956
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subjects Buckminsterfullerene
C60
Channels
device simulation
Drains
Electrodes
Field effect transistors
organic electronics
organic field-effect transistors
Parameters
Semiconductor devices
Thickness
vertical field-effect transistors
title Toward High-Output Organic Vertical Field Effect Transistors: Key Design Parameters
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