Cavendish Laboratory, JJ Thomson Avenue, Cambridge CB30HE, United Kingdom.
ACS Nano. 2010 Mar 23;4(3):1451-6. doi: 10.1021/nn9014664.
In this work we demonstrate two building blocks of a scalable manufacturing technology for nanoscale electronic devices based on direct-write printing: an architecture for high-yield printing of electrode gaps with 100 nm dimension and a low-temperature silver complex ink for integration of organic materials with high conductivity metal interconnects. We use single printed droplets that are made to dewet slowly from each other to allow reliable, high yield patterning even in the presence of certain surface defects.
在这项工作中,我们展示了基于直接书写印刷的纳米电子器件可扩展制造技术的两个构建块:一种用于以 100nm 尺寸打印电极间隙的高产率的架构,以及一种用于将有机材料与高导电性金属互连集成的低温银配合物油墨。我们使用单个印刷液滴,使它们彼此缓慢地脱湿,从而即使在存在某些表面缺陷的情况下,也能实现可靠、高产率的图案化。
