Effects of Post-Annealing on the Properties of ZnO:Ga Films with High Transparency (94%) and Low Sheet Resistance (29 Ω/square)

• Published in: Materials Vol. 16; no. 19; p. 6463
• Main Authors: Wang, Li-Wen, Chu, Sheng-Yuan
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 28.09.2023; MDPI
• Subjects: Aluminum; Annealing; Chemical bonds; Crystallinity; Electrical resistivity; Film thickness; Gallium; gallium zinc oxide; Gases; Glass substrates; Hydrogen; Indium tin oxides; Nitrogen; Optoelectronics; Oxygen; sheet resistance; Temperature; Thin films; Transmission electron microscopy; transparency; XPS; Zinc oxide; Zinc oxides; United States > US; Japan; Germany
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma16196463

This study presents gallium-doped zinc oxide (ZnO:Ga, GZO) thin films. GZO thin films with both high transparency and low sheet resistance were prepared by RF sputtering and then post-annealed under nitrogen and hydrogen forming gas. With post-annealing at 450 °C, the proposed films with a film thickness of 100 nm showed high transparency (94%), while the sheet resistance of the films was reduced to 29 Ω/square, which was comparable with the performances of commercial indium tin oxide (ITO) samples. Post-annealing under nitrogen and hydrogen forming gas enhanced the films’ conductivity while altering the thin-film composition and crystallinity. Nitrogen gas played a role in improving the crystallinity while maintaining the oxygen vacancy of the proposed films, whereas hydrogen did not dope into the thin film, thus maintaining its transparency. Furthermore, hydrogen lowered the resistance of GZO thin films during the annealing process. Then, the detailed mechanisms were discussed. Hydrogen post-annealing helped in the removal of oxygen, therefore increasing the Ga3+ content, which provided extra electrons to lower the resistivity of the films. After the preferable nitrogen/hydrogen forming gas treatment, our proposed films maintained high transparency and low sheet resistance, thus being highly useful for further opto-electronic applications.