Title :
Fully Current-Based Sub-Bandgap Optoelectronic Differential Ideality Factor Technique and Extraction of Subgap DOS in Amorphous Semiconductor TFTs
Author :
Hagyoul Bae ; Hyojoon Seo ; Sungwoo Jun ; Hyunjun Choi ; Jaeyeop Ahn ; Junseok Hwang ; Jungmin Lee ; Oh, Sung-Min ; Jong-Uk Bae ; Sung-Jin Choi ; Dae Hwan Kim ; Dong Myong Kim
Author_Institution :
Kookmin Univ., Seoul, South Korea
Abstract :
A sub-bandgap optoelectronic differential ideality factor technique is proposed for extraction of the intrinsic density-of-states (DOS) over the bandgap in amorphous semiconductor thin-film transistors (TFTs). In the proposed technique, the gate bias-dependent differential change in the difference of ideality factors (dAη(VGS)/dVGS) between dark and sub-bandgap photonic excitation condition is employed. With the sub-bandgap photons (hν <; Eg), the photonic excitation of electrons is confined only from the localized DOS over the bandgap. We applied the proposed technique to a-InGaZnO TFTs with W/L = 50/25 μm/μm and extracted the energy distribution of the intrinsic DOS for the localized states over the bandgap.
Keywords :
amorphous semiconductors; gallium compounds; indium compounds; localised states; thin film transistors; wide band gap semiconductors; zinc compounds; InGaZnO; amorphous semiconductor TFTs; dark photonic excitation condition; energy distribution; fully current-based sub-bandgap optoelectronic differential ideality factor technique; gate bias-dependent differential change; intrinsic density-of-state extraction; localized states; sub-bandgap photonic excitation condition; subgap DOS extraction; thin-film transistors; Capacitance; Logic gates; Optical pumping; Photonic band gap; Photonics; Thin film transistors; Amorphous oxide semiconductor; InGaZnO (IGZO); TFT; density-of-states (DOS); differential ideality factor; optoelectronic; subgap thin-film transistor (TFT); subthreshold;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2348592
