材料科学
铜
柔性电子器件
镍
导电油墨
导电体
合金
印刷电子产品
数码产品
退火(玻璃)
烧结
纳米技术
丝网印刷
墨水池
冶金
薄板电阻
复合材料
图层(电子)
电气工程
工程类
作者
Wanli Li,Lingying Li,Fei Li,Kohsaku Kawakami,Qingqing Sun,Tomonobu Nakayama,Xuying Liu,Masayuki Kanehara,Jie Zhang,Takeo Minari
标识
DOI:10.1021/acsami.1c21633
摘要
Cost-effective copper conductive inks are considered as the most promising alternative to expensive silver conductive inks for use in printed electronics. However, the low stability and high sintering temperature of copper inks hinder their practical application. Herein, we develop rapidly customizable and stable copper-nickel complex inks that can be transformed in situ into uniform copper@nickel core-shell nanostructures by a self-organized process during low-temperature annealing and immediately sintered under photon irradiation to form copper-nickel alloy patterns on flexible substrates. The complex inks are synthesized within 15 min via a simple mixing process and are particle-free, air-stable, and compatible with large-area screen printing. The manufactured patterns exhibit a high conductivity of 19-67 μΩ·cm, with the value depending on the nickel content, and can maintain high oxidation resistance at 180 °C even when the nickel content is as low as 6 wt %. In addition, the printed copper-nickel alloy patterns exhibit high flexibility as a consequence of the local softening and mechanical anchoring effect between the metal pattern and the flexible substrate, showing strong potential in the additive manufacturing of highly reliable flexible electronics, such as flexible radio-frequency identification (RFID) tags and various wearable sensors.
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