posted on 2025-01-02, 07:43authored byYing Liu, Manman Zhang, Chiyu Wang, Xianrui Meng, Xiaomin Fang, Wenkai Zhang, Tao Ding, Dun Liu, Gil Ju Lee, Xudong Chen
Optical
physical unclonable functions (PUFs) are gaining attention
as a robust security solution for identification in the expanding
Internet of Things (IoT). To enhance the security and functionality
of PUFs, integrating multiple optical responsessuch as fluorescence
and structural colorinto a single system is essential. These
diverse optical properties enable multilevel authentication, where
different layers of security can be verified under varying light conditions,
greatly reducing the risk of counterfeiting. However, compactly integrating
these photonic components poses significant challenges due to the
difficulty of aligning and combining their optical behaviors within
a limited space. In this study, we address these challenges by employing
a template-guided assembly of organosilica nanodots (OSiNDs), which
allows for the simultaneous control of solid-state fluorescence, rainbow
holography, and PUF patterns. By precisely tuning the dewetting process,
the OSiNDs assemble into nanoisland structures that provide enhanced
fluorescence brightness and thermal stability while maintaining distinct
holographic properties. Our system produces a 4096-bit key with 3228
bits of entropy, a storage density of 1 Gbit/in2, and a
low false positive rate of 10–6. Additionally, it
includes multilevel anticounterfeiting features that reveal distinct
color patterns under different illumination angles, further boosting
security. Comprehensive environmental stability and durability tests,
including humidity, thermal, and mechanical abrasion resistance, confirm
the robustness of the system, ensuring its functionality under real-world
conditions. This multifunctional PUF design establishes a standard
for secure, compact optical systems, combining high-performance authentication
with practical applications in anticounterfeiting.