Effect of oxygen plasma on the surface states of ZnO films used to produce thin-film transistors on soft plastic sheets

• Published in: Journal of materials chemistry. C, Materials for optical and electronic devices Vol. 1; no. 40; pp. 6613 - 6622
• Main Authors: Meena, Jagan Singh, Chu, Min-Ching, Chang, Yu-Cheng, You, Hsin-Chiang, Singh, Ranjodh, Liu, Po-Tsun, Shieh, Han-Ping D., Chang, Feng-Chih, Ko, Fu-Hsiang
• Format: Journal Article
• Language: English
• Published: 01.01.2013
• Subjects: Density; Deposition; Droplets; Electronic devices; Electronics; Semiconductor devices; Thin film transistors; Zinc oxide
• ISSN: 2050-7526; 2050-7534
• DOI: 10.1039/c3tc31320d

Electronic displays and flexible electronics are poised to significantly impact emerging industries, including displays, energy products, sensors and medical devices, building a market that will significantly grow in the future. The implementation of transparent electronic devices requires the use of material components that could be formed using controlled deposition in the appropriate orientation onto a transparent flexible substrate. Here, we report a simple and efficient means of depositing onto a flexible polyimide (PI) substrate a highly ordered and highly aligned zinc oxide (ZnO) film for use as a carrier transporting and semiconducting layer with controlled surface charge density for thin-film transistor (TFT) applications. The deposition approach is based on the solution-coating of a zinc-acetate suspension under controlled conditions of the spread flow rate, droplet size of the drops, speed limit, and the oxygen (ca.O sub(2)) plasma treatment of the coated film surface on the PI substrate. The plasma surface interactions on the surface states of the ZnO films for various times (ca.1-5 min) were studied using X-ray photoelectron spectroscopy and Fourier transform infrared spectroscopy. Moreover, the effects of O sub(2) plasma and the subsequent thermal annealing in an O sub(2) atmosphere at 250 degree C on the properties of ZnO films were studied for its efficacy in TFT applications in terms of the charge carrier density and the change in the mobility. ZnO thin-film-based TFTs on PI exhibited a very high electron mobility of 22.8 cm super(2) V super(-1) s super(-1) at a drain bias of 5 V after treatment with O sub(2) plasma for 2 min. Furthermore, the plasma treatment for long durations of time caused a reduction in the charge carrier density from 1.58 10 super(19) cm super(-3) for the 2 min treatment to 1.13 10 super(17) cm super(-3) for the 5 min treatment, and the corresponding electron mobility was changed from 22.8 and 3.1 cm super(2) V super(-1) s super(-1) for the treatment times of 2 min and 5 min, respectively. The spin-coating technique used to deposit very thin ZnO films is currently used in microelectronics technology, which helps to ensure that the described ZnO thin-film deposition approach can be implemented in production lines with minimal changes in the fabrication design and in the auxiliary tools used in flexible electronics production.