利用硝酸铜氢氧化物墨水的强脉冲光处理来制造元素铜。

Fabrication of Elemental Copper by Intense Pulsed Light Processing of a Copper Nitrate Hydroxide Ink.

机构信息

†Department of Chemical Engineering, J. B. Speed School of Engineering, University of Louisville, Louisville, Kentucky 40292, United States.

‡Conn Center for Renewable Energy Research, University of Louisville, Louisville, Kentucky 40292, United States.

出版信息

ACS Appl Mater Interfaces. 2015 Aug 5;7(30):16478-85. doi: 10.1021/acsami.5b03854. Epub 2015 Jul 23.

DOI:10.1021/acsami.5b03854

PMID:26154246

Abstract

Printed electronics and renewable energy technologies have shown a growing demand for scalable copper and copper precursor inks. An alternative copper precursor ink of copper nitrate hydroxide, Cu2(OH)3NO3, was aqueously synthesized under ambient conditions with copper nitrate and potassium hydroxide reagents. Films were deposited by screen-printing and subsequently processed with intense pulsed light. The Cu2(OH)3NO3 quickly transformed in less than 100 s using 40 (2 ms, 12.8 J cm(-2)) pulses into CuO. At higher energy densities, the sintering improved the bulk film quality. The direct formation of Cu from the Cu2(OH)3NO3 requires a reducing agent; therefore, fructose and glucose were added to the inks. Rather than oxidizing, the thermal decomposition of the sugars led to a reducing environment and direct conversion of the films into elemental copper. The chemical and physical transformations were studied with XRD, SEM, FTIR and UV-vis.

摘要

印刷电子和可再生能源技术对可扩展的铜和铜前体墨水表现出越来越大的需求。一种替代的铜前体墨水是硝酸铜氢氧化物，Cu2(OH)3NO3，在环境条件下，以硝酸铜和氢氧化钾试剂水合成。薄膜通过丝网印刷沉积，然后用强脉冲光进行处理。Cu2(OH)3NO3 在不到 100 秒的时间内使用 40 个（2 ms，12.8 J cm(-2)) 脉冲迅速转化为 CuO。在更高的能量密度下，烧结提高了整体薄膜质量。Cu2(OH)3NO3 直接形成 Cu 需要还原剂；因此，在墨水中添加了果糖和葡萄糖。糖的热分解不是氧化，而是导致还原环境，并将薄膜直接转化为元素铜。化学和物理转化通过 XRD、SEM、FTIR 和 UV-vis 进行了研究。

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利用硝酸铜氢氧化物墨水的强脉冲光处理来制造元素铜。

Fabrication of Elemental Copper by Intense Pulsed Light Processing of a Copper Nitrate Hydroxide Ink.

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