Mass production roll-to-roll printing techniques such as flexography, gravure, and offset are undergoing re-examination for their suitability in the emerging area of printed electronics. These methods rely on high speed ink-transfer mechanisms using direct print-form to substrate contact. Commonly occurring defects such as haloing, featuring, and bridging can impact the performance of printed materials for electronics applications. To improve the viability of these approaches, strategies are needed to increase print fidelity and film uniformity.

About

Sandia researchers have developed a microscale print form that can achieve very fine, tunable features and exceptional control during liquid transfer printing processes. The stamp is designed with tunable and layered Poisson's ratio to dictate capillary forces that effectively meter fluid transfer through architected porosity. The print form was fabricated using multiphoton lithography (MPL), a microscale additive manufacturing technique that enables submicron feature sizes. This new technique offers advanced control of fluid uptake and dispensing and can be used to develop more sophisticated liquid transfer processes for emerging applications such as solar cell metallization and printed circuits.

Key Benefits

Improved efficiency and performance in mass production applications Reduced defects and blemishes with higher throughput

Applications

Additive manufacturing (specifically high-speed roll-to-roll flexography) Printed electronics and components Medical device fabrication Textile production

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