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In Advanced materials (Deerfield Beach, Fla.)

Printed electronics promises to drive the future data-intensive technologies, with its potential to fabricate novel devices over large-area with low cost on non-traditional substrates. In these emerging technologies, there exists a large digital information flow, which requires secure communication and authentication. Physical unclonable functions (PUFs) offer a promising built-in hardware-security system comparable to biometrical data, which can be constructed by device-specific intrinsic variations in the additive manufacturing process of active devices. However, printed PUFs typically exploit the inherent variation in layer thickness and roughness of active devices. The current in the devices with enough significant changes to increase the robustness to external environment noise is still a challenge. Here, we demonstrated printable epsilon-type structure ITO transistor arrays to construct high-reliability PUFs by modifying the coffee-ring structure. The epsilon-type structure improves the printing scalability, film quality, and device reliability. Furthermore, the print-induced uncertainty along the channel thickness and length can lead to changes in the carrier concentration. Notably, the randomly distributed printing droplets in a small area significantly increase this uncertainty. As a result, the PUFs exhibit near-ideal uniformity, uniqueness, randomness, and reliability. Additionally, the PUFs are resilient against machine learning-based attacks with a prediction accuracy of only 55% without post-processing. This article is protected by copyright. All rights reserved.

Wang Rui, Liang Kun, Wang Saisai, Cao Yaxiong, Xin Yuhan, Peng Yaqian, Ma Xiaohua, Zhu Bowen, Wang Hong, Hao Yue

2023-Feb-02

coffee-ring effect, hardware security, metal-oxide transistors, physical unclonable functions, printed electronics