Low-frequency noise(LFN) in all operation regions of amorphous indium zinc oxide(a-IZO) thin film transistors(TFTs) with an aluminum oxide gate insulator is investigated. Based on the LFN measured results, we ex...Low-frequency noise(LFN) in all operation regions of amorphous indium zinc oxide(a-IZO) thin film transistors(TFTs) with an aluminum oxide gate insulator is investigated. Based on the LFN measured results, we extract the distribution of localized states in the band gap and the spatial distribution of border traps in the gate dielectric,and study the dependence of measured noise on the characteristic temperature of localized states for a-IZO TFTs with Al2 O3 gate dielectric. Further study on the LFN measured results shows that the gate voltage dependent noise data closely obey the mobility fluctuation model, and the average Hooge's parameter is about 1.18×10^-3.Considering the relationship between the free carrier number and the field effect mobility, we simulate the LFN using the △N-△μ model, and the total trap density near the IZO/oxide interface is about 1.23×10^18 cm^-3eV^-1.展开更多
基金Supported by the National Natural Science Foundation of China under Grant No 61574048the Science and Technology Research Project of Guangdong Province under Grant Nos 2015B090912002 and 2015B090901048the Pearl River S&T Nova Program of Guangzhou under Grant No 201710010172
文摘Low-frequency noise(LFN) in all operation regions of amorphous indium zinc oxide(a-IZO) thin film transistors(TFTs) with an aluminum oxide gate insulator is investigated. Based on the LFN measured results, we extract the distribution of localized states in the band gap and the spatial distribution of border traps in the gate dielectric,and study the dependence of measured noise on the characteristic temperature of localized states for a-IZO TFTs with Al2 O3 gate dielectric. Further study on the LFN measured results shows that the gate voltage dependent noise data closely obey the mobility fluctuation model, and the average Hooge's parameter is about 1.18×10^-3.Considering the relationship between the free carrier number and the field effect mobility, we simulate the LFN using the △N-△μ model, and the total trap density near the IZO/oxide interface is about 1.23×10^18 cm^-3eV^-1.
