Hydrocipher: Bioinspired Dynamic Structural Color-Based Cryptographic Surface

Jaeho Choi, Mutian Hua, Seung Yeol Lee, Wonhee Jo, Chiao Yueh Lo, Shin Hyun Kim, Hee Tak Kim, Ximin He

Research output: Contribution to journalArticlepeer-review

49 Scopus citations

Abstract

Structural colors of 2D gratings are iridescent, color-tunable, and never fade, which renders them appealing for anti-counterfeiting applications. However, for advanced security, it still remains a challenge to completely hide the encrypted color patterns and reveal them on demand. In this work, a water-responsive photonic grating consisting of a micropillar array and a hydrogel overcoat with a similar refractive index, termed “hydrocipher”, is presented. The joint effect of stimuli-reversible refractive-index (mis)match and reconfigurable grating-based diffraction coloration enables a complete encryption of the structural color and rapid decryption. The photonic structure shows a strong iridescence due to the angle-dependent diffraction when the hydrogel overcoat is swollen from water. Upon drying, the micropillars bend and the refractive index contrast disappears, which dramatically lessens the diffraction intensity and renders the surface highly transparent. The dehydrated-to-hydrated state transition can occur within 1 s, enabling fast decryption. The color switching is highly reversible over a prolonged hydration/dehydration cycle, and the dehydrated hydrogel layer protects the delicate micropillar array from external mechanical stress. The creative combination of hydrogel material and the 2D grating structure offers a new and simple strategy for realizing reversible, durable, and fast-response cryptography with potentially broad impact on the anti-counterfeiting technology market.

Original languageEnglish
Article number1901259
JournalAdvanced Optical Materials
Volume8
Issue number1
DOIs
StatePublished - 1 Jan 2020

Keywords

  • 2D gratings
  • anti-counterfeit tags
  • hydrogels
  • micropillars
  • structural colors

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