Laser-induced digital oxidation for copper-based flexible photodetectors

• Published in: Applied surface science Vol. 540; p. 148333
• Main Authors: Kwon, Hyeokjin, Kim, Junil, Ko, Kyungmin, Matthews, Manyalibo J., Suh, Joonki, Kwon, Hyuk-Jun, Yoo, Jae-Hyuck
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 28.02.2021
• Subjects: Copper; Flexible electronics; Laser; Oxidation; Photodetectors; Oxidation; Photodetectors; Copper; Flexible electronics; Laser
• ISSN: 0169-4332; 1873-5584
• DOI: 10.1016/j.apsusc.2020.148333

[Display omitted] •Photodetectors are manufactured by one step laser-induced Cu oxidation.•Raman and XPS data are used to verify the composition of CuxO.•Scanning photocurrent data are used to explain carrier transport mechanisms.•Transient photo-response is captured to present the performance of photodetectors. Copper oxide compounds (CuxO) with bandgaps of 1.3–2.1 eV (CuO) and 2.1–2.6 eV (Cu2O) have been investigated as promising p-type semiconducting materials. CuxO is generally obtained by deposition or thermal oxidation, but those methods are not optimal for flexible substrates. Furthermore, additional patterning steps are required to fabricate devices. We present an easy, controllable method to fabricate a metal-semiconductor-metal (MSM) photodetector using laser-induced oxidation of a thin Cu film. After laser irradiation, the Cu film is heated under ambient conditions, and this leads to a thermal oxidation reaction, in which Cu oxide is monolithically formed in the Cu film and a Cu-CuxO-Cu MSM structure is produced. Since the laser offers localized heating, an arbitrary CuxO pattern can be written in the Cu film by spatially controlled heating. In addition, by optimizing the heating time, the laser-induced oxidation can be successfully performed even on a flexible substrate. To study the laser-induced oxidation, we examined the correlation between laser parameters and the oxidation pattern and analyzed the composition using scanning electron microscopy, Raman spectroscopy, and X-ray photoemission spectroscopy. Furthermore, we measured the transient photoresponse and employed scanning photocurrent microscopy to investigate the mechanism of carrier transport behavior.