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Reversible optical data storage and encryption enabled by phase-change and hydrogel integration

07.15.26 | Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS
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The rapid expansion of the digital age continues to push the limits of data storage technologies, demanding not only higher capacity but also enhanced security and intuitive accessibility. Optical approaches have long been considered a promising alternative to conventional electronic storage, offering advantages such as high density and long-term stability. However, most existing optical storage device are static, require expensive fabrication methods like electron-beam lithography and often rely on carefully controlled illumination conditions—such as specific wavelengths, polarization states, or viewing angles, thus restricting their practicality outside laboratory settings.

Researchers at the University of California, San Diego ( NDAO lab: N ano D evices and A pplied O ptics) have developed a new class of optical storage technology that can dynamically hide and reveal different images within a controlled-humidity chamber. Rather than requiring specialized optics, the device operates under ambient light, making it inherently accessible and user-friendly. The device offers robust rewritability via the phase-change Sb₂S₃ layer, enabling optical information to be repeatedly written, erased, and reprogrammed via controlled laser irradiation. The work, recently published in Light: Science & Applications , introduces a multifunctional platform that combines phase-change materials with responsive hydrogels to enable reversible, full-color image multiplexing for high-density storage devices.

The device combines two distinct yet complementary materials within a single multilayer structure. A phase-change material stores rewritable information through laser-induced structural transitions, while a humidity-responsive UV-programmable hydrogel introduces two functionalities: a new layer for data storage and dynamic optical modulation that depends on environmental conditions.

"In one of the device’s most striking features, the authors demonstrated a dynamic transition where a 'UCSD Triton' logo visible at low humidity (~40% RH) transforms into a full-color 'UCSD Library' logo as humidity increases to 85%."

“Our approach enables multiple images to be stored within a single compact structure and retrieved selectively using a simple environmental trigger without requiring a specialized light source,” said the research team. “This represents a significant step toward practical, user-friendly optical encryption technologies and displays.”

This work establishes a versatile platform for next-generation optical information technologies, where multiple data channels can be encoded, concealed, and dynamically accessed within a single device. Future developments could extend this concept to multi-stimuli-responsive systems, enabling control through temperature, electric fields, or chemical environments for more sophisticated data encryption and adaptive displays. This technology could enable adaptive AR/VR optics, in which optical elements dynamically tune color, contrast, or information layers in response to environmental conditions without additional electronics. In photonics, the platform introduces reconfigurable optical components—such as tunable filters, smart waveguides, and dynamic color elements—supporting next-generation systems for sensing, secure communication, and programmable light–matter interaction. The scalability and low-cost fabrication also position the technology for practical deployment in anti-counterfeiting, smart packaging, and wearable sensing.

Light: Science & Applications

10.1038/s41377-026-02330-5

Reversible Optical Data Storage and Encryption Enabled by Phase-Change and Hydrogel Integration

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Article Information

Contact Information

WEI ZHAO
Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS
zhaowei@lightpublishing.cn

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This article is based on a news release from Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS. BrightSurf curates and republishes science news from research institutions worldwide; the original release is linked below.

How to Cite This Article

APA:
Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS. (2026, July 15). Reversible optical data storage and encryption enabled by phase-change and hydrogel integration. Brightsurf News. https://www.brightsurf.com/news/12DG35O1/reversible-optical-data-storage-and-encryption-enabled-by-phase-change-and-hydrogel-integration.html
MLA:
"Reversible optical data storage and encryption enabled by phase-change and hydrogel integration." Brightsurf News, Jul. 15 2026, https://www.brightsurf.com/news/12DG35O1/reversible-optical-data-storage-and-encryption-enabled-by-phase-change-and-hydrogel-integration.html.