Laser printed microelectronics

Printed organic and inorganic electronics continue to be of large interest for several applications. Here, the authors propose laser printing as a facile process for fabricating printed electronics with minimum feature sizes below 1 mu m and demonstrate functional diodes, memristors, and physically unclonable functions. Printed organic and inorganic electronics continue to be of large interest for sensors, bioelectronics, and security applications. Many printing techniques have been investigated, albeit often with typical minimum feature sizes in the tens of micrometer range and requiring post-processing procedures at elevated temperatures to enhance the performance of functional materials. Herein, we introduce laser printing with three different inks, for the semiconductor ZnO and the metals Pt and Ag, as a facile process for fabricating printed functional electronic devices with minimum feature sizes below 1 mu m. The ZnO printing is based on laser-induced hydrothermal synthesis. Importantly, no sintering of any sort needs to be performed after laser printing for any of the three materials. To demonstrate the versatility of our approach, we show functional diodes, memristors, and a physically unclonable function based on a 6 x 6 memristor crossbar architecture. In addition, we realize functional transistors by combining laser printing and inkjet printing.

Automated summary

The authors propose laser printing as a facile process for fabricating printed electronics with minimum feature sizes below 1μm and demonstrate functional diodes, memristors, and physically unclonable functions. Laser printing with different inks, for the semiconductor ZnO and the metals Pt and Ag, is introduced for fabricating printed functional electronic devices with minimum feature sizes below 1μm. The versatility of this approach is demonstrated by showing functional diodes, memristors, and a physically unclonable function.