Self-Aligned Ionic Doping of TiO 2 Thin-Film Transistors for Enhanced Current Drivability via Postfabrication Superacid Treatment.
Jie ZhangHaochen ZhaoXiaofeng YeMeng JiaGuangyang LinZe YangYifeng WangShubo WeiYingzhen LinQingxuan SunTuofu ZhamaWeifeng YangYuping ZengPublished in: ACS applied materials & interfaces (2024)
Oxide semiconductor thin-film transistors (TFTs) have shown great potential in emerging applications such as flexible displays, radio-frequency identification tags, sensors, and back-end-of-line compatible transistors for monolithic 3D integration beyond their well-established flat-plane display technology. To meet the requirements of these appealing applications, high current drivability is essential, necessitating exploration in materials science and device engineering. In this work, we report for the first time on a simple solution-based superacid (SA) treatment to enhance the current drivability of top-gate TiO 2 TFTs with a gate-offset structure. The on-current of these transistors is limited by the relatively low mobility of TiO 2 due to its d-orbital conduction nature. It is found that the on-current of TiO 2 TFTs is nearly doubled via a quick dip in a SA solution at room temperature in ambient air. A series of experiments, including comparative I - V measurements of TFTs with different treatments and gate structures, C - V measurements, X-ray photoelectron spectroscopy, time-of-flight secondary ion mass spectrometry, and device simulation, were performed to uncover the underlying reason for the current enhancement. It is believed that the protons (H + ) from SA are doped into the offset region of TiO 2 TFTs, forming an electron double layer and thus boosting the on-current, with the top gate serving as a self-aligned mask for ionic doping. Furthermore, the ionic size and the proportion of the offset region to the channel play crucial roles in the effectiveness of ionic doping, while the position of the incorporated ions, whether in the channel or dielectric, may result in distinct shifts in the turn-on voltage ( V ON ) and affect the functionality of ionic doping. This study provides a pathway for enhancing the current drivability of TiO 2 TFTs via selective ionic doping enabled by SA treatment and deepens our understanding of ion incorporation in electronic devices. This approach could be applicable to other material systems and may also benefit TFTs with miniaturized dimensions, thus opening up unprecedented opportunities for TiO 2 TFTs in future applications requiring high current drivability.
Keyphrases
- quantum dots
- ionic liquid
- room temperature
- mass spectrometry
- solid state
- high resolution
- visible light
- systematic review
- randomized controlled trial
- public health
- air pollution
- single molecule
- obstructive sleep apnea
- combination therapy
- magnetic resonance
- climate change
- sensitive detection
- liquid chromatography
- human health