Abstract
We fabricated the transparent non-volatile memory (NVM) of a bottom gate thin film transistor (TFT) for the integrated logic devices of display applications. The NVM TFT utilized indium–tin–zinc–oxide (ITZO) as an active channel layer and multi-oxide structure of SiO2 (blocking layer)/Si-rich SiOX (charge trapping layer)/SiOXNY (tunneling layer) as a gate insulator. The insulators were deposited using inductive coupled plasma chemical vapor deposition, and during the deposition, the trap states of the Si-rich SiOx charge trapping layer could be controlled to widen the memory window with the gas ratio (GR) of SiH4:N2O, which was confirmed by fourier transform infrared spectroscopy (FT-IR). We fabricated the metal–insulator–silicon (MIS) capacitors of the insulator structures on n-type Si substrate and demonstrated that the hysteresis capacitive curves of the MIS capacitors were a function of sweep voltage and trap density (or GR). At the GR6 (SiH4:N2O = 30:5), the MIS capacitor exhibited the widest memory window; the flat band voltage (ΔVFB) shifts of 4.45 V was obtained at the sweep voltage of ±11 V for 10 s, and it was expected to maintain ~71% of the initial value after 10 years. Using the Si-rich SiOX charge trapping layer deposited at the GR6 condition, we fabricated a bottom gate ITZO NVM TFT showing excellent drain current to gate voltage transfer characteristics. The field-effect mobility of 27.2 cm2/Vs, threshold voltage of 0.15 V, subthreshold swing of 0.17 V/dec, and on/off current ratio of 7.57 × 107 were obtained at the initial sweep of the devices. As an NVM, ΔVFB was shifted by 2.08 V in the programing mode with a positive gate voltage pulse of 11 V and 1 μs. The ΔVFB was returned to the pristine condition with a negative voltage pulse of −1 V and 1 μs under a 400–700 nm light illumination of ~10 mWcm−2 in erasing mode, when the light excites the electrons to escape from the charge trapping layer. Using this operation condition, ~90% (1.87 V) of initial ΔVFB (2.08 V) was expected to be retained over 10 years. The developed transparent NVM using Si-rich SiOx and ITZO can be a promising candidate for future display devices integrating logic devices on panels.
Highlights
The ionic bonded amorphous oxide semiconductor (AOS) materials with a large optical bandgap were introduced for the applications of transparent electrode like indium tin oxide (ITO) or zinc oxide (ZnO) [1]
Yin et al reported on an non-volatile memory (NVM) with a bottom gate n-type IGZO thin film transistor (TFT) structure [10,11] of IGZO/Al2O3/IGZO/Al2O3/Mo layers; low VTH of 0.7 V and high field-effect mobility of 10.3 cm2/Vs are exhibited, but reliability characteristics were still so poor that the program/erase cycles and retention time were less than 103 times and 103 s, respectively
At the positive bias voltage, electrons, the majority carriers of Si channel were accumulated at the interface to the SiOXNY, the MIS capacitance was close to that of the overall insulator capacitor of SiO2/Si-rich oxide (SiOX)/SiOXNY (COX, ~8.48 × 10−8 F/cm2)
Summary
The ionic bonded amorphous oxide semiconductor (AOS) materials with a large optical bandgap were introduced for the applications of transparent electrode like indium tin oxide (ITO) or zinc oxide (ZnO) [1]. The basic operating of NVM devices is to store charges in a dielectric layer; when charges are trapped or detrapped in the dielectric layer of an NVM transistor, the threshold voltage (VTH) of the transistor can be altered between two states as programming and erasing states.
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