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Rapid photonic curing effects of xenon flash lamp on ITO–Ag–ITO multilayer electrodes for high throughput transparent electronics

Zhenqian Zhao, Alex Rose, Sang Jik Kwon, Yongmin Jeon, Eou‐Sik Cho

2023Scientific Reports12 citationsDOIOpen Access PDF

Abstract

High-throughput transparent and flexible electronics are essential technologies for next-generation displays, semiconductors, and wearable bio-medical applications. However, to manufacture a high-quality transparent and flexible electrode, conventional annealing processes generally require 5 min or more at a high temperature condition of 300 °C or higher. This high thermal budget condition is not only difficult to apply to general polymer-based flexible substrates, but also results in low-throughput. Here, we report a high-quality transparent electrode produced with an extremely low thermal budget using Xe-flash lamp rapid photonic curing. Photonic curing is an extremely short time (~ μs) process, making it possible to induce an annealing effect of over 800 °C. The photonic curing effect was optimized by selecting the appropriate power density, the irradiation energy of the Xe-flash lamp, and Ag layer thickness. Rapid photonic curing produced an ITO-Ag-ITO electrode with a low sheet resistance of 6.5 ohm/sq, with a high luminous transmittance of 92.34%. The low thermal budget characteristics of the rapid photonic curing technology make it suitable for high-quality transparent electronics and high-throughput processes such as roll-to-roll.

Topics & Concepts

ElectrodeThroughputOptoelectronicsPhotonicsMaterials scienceElectronicsCuring (chemistry)XenonFlash-lampComputer scienceChemistryTelecommunicationsComposite materialWirelessPhysical chemistryOrganic chemistryZnO doping and propertiesTransition Metal Oxide NanomaterialsThin-Film Transistor Technologies
Rapid photonic curing effects of xenon flash lamp on ITO–Ag–ITO multilayer electrodes for high throughput transparent electronics | Litcius