Scaling and Optimization of Gravure-Printed Silver Nanoparticle Lines for Printed Electronics

IEEE Transactions on Components and Packaging Technologies Pub Date : 2010-03-01 DOI:10.1109/TCAPT.2009.2021464

D. Sung, A. de la Fuente Vornbrock, V. Subramanian

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引用次数: 133

Abstract

Printed electronics promises to enable new applications such as RFID tags, displays and various types of sensors. Critical to the development of printed electronics is the establishment of a manufacturable printing technique with high resolution and throughput. Gravure is a high-speed roll-to-roll printing technique that has many of the characteristics necessary for a viable printed electronics process. We present the first systematic study on the scaling and optimization of conductive lines for printed electronics, especially with high viscosity nanoparticle inks. We demonstrate gravure-printed nanoparticle lines, which are potentially suitable for use in thin-film transistor (TFT) based circuits as well as passive components. We present several trends observed by varying cell and ink parameters, and compare two different techniques for printing lines. We examine current limits to scaling printed lines and demonstrate the potential viability and scalability of gravure for printed electronics.

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印刷电子用凹印纳米银颗粒线的缩放与优化

印刷电子产品有望实现新的应用，如RFID标签、显示器和各种类型的传感器。印刷电子技术发展的关键是建立一种具有高分辨率和吞吐量的可制造印刷技术。凹印是一种高速卷对卷印刷技术，具有可行的印刷电子工艺所需的许多特性。我们首次系统地研究了印刷电子产品的导电线的缩放和优化，特别是高粘度纳米颗粒油墨。我们展示了凹印纳米颗粒线，它可能适用于基于薄膜晶体管(TFT)的电路以及无源元件。我们提出了几个趋势观察不同的细胞和油墨参数，并比较两种不同的技术印刷线。我们研究了当前缩放印刷线的限制，并展示了凹印印刷电子产品的潜在可行性和可扩展性。

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IEEE Transactions on Components and Packaging Technologies 工程技术-材料科学：综合

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