Chemical potential shift in organic field-effect transistors identified by soft X-ray operando nano-spectroscopy

Naoka Nagamura; Yuta Kitada; Junto Tsurumi; Hiroyuki Matsui; Koji Horiba; Itaru Honma; Jun Takeya; Masaharu Oshima

doi:10.1063/1.4922902

Chemical potential shift in organic field-effect transistors identified by soft X-ray operando nano-spectroscopy

Naoka Nagamura, Yuta Kitada, Junto Tsurumi, Hiroyuki Matsui, Koji Horiba, Itaru Honma, Jun Takeya, Masaharu Oshima

IMRAM - Center for Mineral Processing and Metallurgy (CMPM)

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

A chemical potential shift in an organic field effect transistor (OFET) during operation has been revealed by soft X-ray operando nano-spectroscopy analysis performed using a three-dimensional nanoscale electron-spectroscopy chemical analysis system. OFETs were fabricated using ultrathin (3 ML or 12 nm) single-crystalline C10-DNBDT-NW films on SiO₂ (200 nm)/Si substrates with a backgate electrode and top source/drain Au electrodes, and C 1s line profiles under biasing at the backgate and drain electrodes were measured. When applying -30 V to the backgate, there is C 1s core level shift of 0.1 eV; this shift can be attributed to a chemical potential shift corresponding to band bending by the field effect, resulting in p-type doping.

Original language	English
Article number	251604
Journal	Applied Physics Letters
Volume	106
Issue number	25
DOIs	https://doi.org/10.1063/1.4922902
Publication status	Published - 2015 Jun 22

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title = "Chemical potential shift in organic field-effect transistors identified by soft X-ray operando nano-spectroscopy",

abstract = "A chemical potential shift in an organic field effect transistor (OFET) during operation has been revealed by soft X-ray operando nano-spectroscopy analysis performed using a three-dimensional nanoscale electron-spectroscopy chemical analysis system. OFETs were fabricated using ultrathin (3 ML or 12 nm) single-crystalline C10-DNBDT-NW films on SiO2 (200 nm)/Si substrates with a backgate electrode and top source/drain Au electrodes, and C 1s line profiles under biasing at the backgate and drain electrodes were measured. When applying -30 V to the backgate, there is C 1s core level shift of 0.1 eV; this shift can be attributed to a chemical potential shift corresponding to band bending by the field effect, resulting in p-type doping.",

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AU - Nagamura, Naoka

AU - Kitada, Yuta

AU - Tsurumi, Junto

AU - Matsui, Hiroyuki

AU - Horiba, Koji

AU - Honma, Itaru

AU - Takeya, Jun

AU - Oshima, Masaharu

PY - 2015/6/22

Y1 - 2015/6/22

N2 - A chemical potential shift in an organic field effect transistor (OFET) during operation has been revealed by soft X-ray operando nano-spectroscopy analysis performed using a three-dimensional nanoscale electron-spectroscopy chemical analysis system. OFETs were fabricated using ultrathin (3 ML or 12 nm) single-crystalline C10-DNBDT-NW films on SiO2 (200 nm)/Si substrates with a backgate electrode and top source/drain Au electrodes, and C 1s line profiles under biasing at the backgate and drain electrodes were measured. When applying -30 V to the backgate, there is C 1s core level shift of 0.1 eV; this shift can be attributed to a chemical potential shift corresponding to band bending by the field effect, resulting in p-type doping.

AB - A chemical potential shift in an organic field effect transistor (OFET) during operation has been revealed by soft X-ray operando nano-spectroscopy analysis performed using a three-dimensional nanoscale electron-spectroscopy chemical analysis system. OFETs were fabricated using ultrathin (3 ML or 12 nm) single-crystalline C10-DNBDT-NW films on SiO2 (200 nm)/Si substrates with a backgate electrode and top source/drain Au electrodes, and C 1s line profiles under biasing at the backgate and drain electrodes were measured. When applying -30 V to the backgate, there is C 1s core level shift of 0.1 eV; this shift can be attributed to a chemical potential shift corresponding to band bending by the field effect, resulting in p-type doping.

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Chemical potential shift in organic field-effect transistors identified by soft X-ray operando nano-spectroscopy

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