AI Article Synopsis
- Researchers are focusing on highly conductive and printable electrodes for cost-effective electronics, which are crucial for large-area applications.
- A flashlight-based sintering technique has been identified as a practical method for creating these electrodes from metallic nanomaterials in a continuous process.
- The study introduces printable Cu electrodes using an innovative ultrathin Ag nanoparticle layer, achieving impressive conductivity metrics while being compatible with delicate PET substrates.
Article Abstract
In recent years, highly conductive, printable electrodes have received tremendous attention in various research fields as the most important constituent components for large-area, low-cost electronics. In terms of an indispensable sintering process for generating electrodes from printable metallic nanomaterials, a flashlight-based sintering technique has been regarded as a viable approach for continuous roll-to-roll processes. In this paper, we report cost-effective, printable Cu electrodes that can be applied to vulnerable polyethylene terephthalate (PET) substrates, by incorporating a heretofore-unrecognized ultrathin plasmonic thermal/optical barrier, which is composed of a 30 nm thick Ag nanoparticle (NP) layer. The different plasmonic behaviors during a flashlight-sintering process are investigated for both Ag and Cu NPs, based on a combined interpretation of the experimental results and theoretical calculations. It is demonstrated that by a continuous printing process and a continuous flashlight-sintering process, the Cu electrodes are formed successfully on large PET substrates, with a sheet resistance of 0.24 Ω/sq and a resistivity of 22.6 μΩ·cm.
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| http://dx.doi.org/10.1021/acsami.7b14654 | DOI Listing |
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