Highly conductive copper films based on submicron copper particles/copper complex inks for printed electronics: Microstructure, resistivity, oxidation resistance, and long-term stability

Submicron Cu particles mixed with Cu complex are used successfully to fabricate highly conductive Cu films for printed electronics. This study investigates the effects of Cu particle size on microstructure, conductivity and on the long-term stability of printed Cu films. In particular, the oxidation...

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Bibliographic Details
Published in:Journal of alloys and compounds 2018-01, Vol.732, p.240-247
Main Authors: Li, Wanli, Li, Lingying, Gao, Yue, Hu, Dawei, Li, Cai-Fu, Zhang, Hao, Jiu, Jinting, Nagao, Shijo, Suganuma, Katsuaki
Format: Article
Language:English
Subjects:
Catalytic oxidation
Conductivity
Coordination compounds
Copper
Copper compounds
Copper oxides
Cu ink
Cu nanoparticles
Electrical resistivity
Electronics
Inks
Metal films
Microstructure
Nanoparticles
Oxidation behaviors
Oxidation resistance
Particle size
Printed electronics
Stability
Studies
Submicron Cu particles
Thermal stability
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Summary:Submicron Cu particles mixed with Cu complex are used successfully to fabricate highly conductive Cu films for printed electronics. This study investigates the effects of Cu particle size on microstructure, conductivity and on the long-term stability of printed Cu films. In particular, the oxidation behaviors of printed Cu films at high temperatures are studied from the evolutions in microstructure and chemical composition. The submicron Cu particles are sintered efficiently due to the help of in-situ formed Cu nanoparticles from the decomposition of the Cu complex. Low resistivity of 5.8 μΩ cm is easily achieved. At temperatures of 140 °C and 180 °C, the printed Cu films prepared from 800 nm Cu particles are more stable than that from those 350 nm particles, which can be attributed to larger Cu particles possessing higher oxidation resistance. At 220 °C, the result becomes opposite because the loose structure with many large voids in the printed Cu films from large particles provides sufficient space for oxygen and accelerate the break of pathways between adjacent particles by the formation of Cu oxides layers. This indicates the long-term stability of printed Cu films is attributed to not only the intrinsic oxidation of Cu to Cu2O but also the degradation of microstructures. At all events, the printed Cu films from submicron Cu particles with Cu complex exhibit excellent oxidation resistance and are superior to those from Cu nanoparticles. This presents significant potential and favorable prospects for the fabrication of highly reliable and cost-effective printed electronics. •Submicron Cu particles are efficiently sintered by in-situ formed Cu nanoparticles.•Effect of particle size on structure and conductivity of printed films is studied.•Effect of Cu particle size on the oxidation behaviors of printed films is studied.•Stability of printed films is attributed to oxidation and microstructure evolution.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2017.10.193