Influence of UV/Ozone Treatment on Threshold Voltage Modulation in Sol-Gel IGZO Thin-Film Transistors

Sol-gel indium-gallium-zinc oxide (IGZO) semiconductors are developed as active components of thin-film transistors (TFTs) because of their high electron mobility, cost-effective large-area fabrication, and applicability for flexible substrates. Controlling oxygen vacancies (V-o) in the IGZO semiconductor channel is always problematic for reliable and long-term operation. Surplus interfacial charges inside the IGZO channel cause negative shifts in threshold voltages (V-th), resulting in depletion-mode operation and involuntary high current output. The room temperature and rapid (<3 min) modulation of V-th using a novel ultraviolet ozone (UVO) treatment of IGZO layer (In:Ga:Zn = 7:1:2) are reported. Physicochemical and electrical analysis reveals that UVO treatment enables the reduction of V-o and increases M-O bonding with invariant contact resistance, resulting in the normalization of V-th close to 0 V and high operational durability under long-term bias stress. As a proof of concept, this study demonstrates the depletion-load n-type inverters comprising depletion and enhancement modes (without & with UVO) on the same substrate that allow high gain (approximate to 10) with a moderate noise margin. This UVO treatment of the active layer is advantageous for the effective modulation of V-th with stable operation under long-term bias stress and is superior to logic inverters based on single-mode sol-gel oxide transistors.

Automated summary

This study reports a novel method to rapidly reduce threshold voltage using ultraviolet ozone treatment of IGZO layer, which decreases oxygen vacancies and increases bonding, resulting in stable operation and long-term durability of transistors. Depletion-mode inverters fabricated on the same substrate exhibit high gain and moderate noise margin.