Compression-Encrypted Meta-Optics for Storage Efficiency and Security Enhancement

Wang, Zejing; Niu, Mengyu; Zhao, Wenjia; Wang, Zhuowen; Wan, Shuai; Shi, Yangyang; Shan, Xin; Li, Zhongyang

doi:10.1021/acsphotonics.3c01519

ACS Photonics

2024

DOI: 10.1021/acsphotonics.3c01519

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Compression-Encrypted Meta-Optics for Storage Efficiency and Security Enhancement

Zejing Wang,

Mengyu Niu,

Wenjia Zhao

et al.

Abstract: Information security is of vital importance in daily life, stimulating various cryptographic strategies to protect data from leaking. Among them, metasurface-based optical encryption is an excellent candidate because of its unique features, including numerous encoding channels and incomparable light-field manipulation ability. However, for state-of-the-art metasurface encryption, it is still critical to further improve its storage efficiency with high security for practical information-storage applications. He… Show more

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Cited by 4 publications

References 34 publications

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Ultra‐High Secure Holographically Steganographic Array with Spatiotemporal Dual‐Encryption Keys

Zhu,

Qi,

Zhang

et al. 2024

Adv Funct Materials

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Independently‐manipulated optical encryption has attracted great attention due to its high security and multiple application scenarios. Although photochromic molecules have become preferred holographic display units, the integration of dynamic modulation both in hologram and fluorescence for orthogonal encryption is still challenged. Herein, a latticed holographically steganographic array is constructed by incorporating a plasticizer (tri‐o‐cresyl phosphate, TOCP) into spirooxazine (SO) based polymers, thereby modulating the isomerization rate and the UV‐fluorescence kinetics between SO and merocyanine (MC). The period to reach fluorescence saturated value for each information bit in the latticed device can be widely modulated between 60 and 1700 s. Based on the property, only through ultraviolet stimulation can array information gradually be converted from spatial lattice coordinates to holographic display time. Then, a hidden 3D image can be determined from rapidly updatable reconstructed hologram video with refresh rate 1.125 Hz by the above spatiotemporal dual‐encryption keys. This work provides a bright path for the ultra‐high safety steganography and adaptive stereoscopic imaging.

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Ultra‐High Secure Holographically Steganographic Array with Spatiotemporal Dual‐Encryption Keys

Zhu,

Qi,

Zhang

et al. 2024

Adv Funct Materials

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Direction‐Decoupled Light‐Emitting Metasurface via Guided‐Photoluminescence Manipulation

Wang,

Wan,

Dai

et al. 2024

Adv Funct Materials

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On‐demand manipulation of light emissions is crucial for a variety of practical applications, including bio‐imaging and optical display, etc. Within this realm, the invention of metasurfaces provides powerful light–matter interaction capabilities for the control of multitudinous emission parameters. However, due to the omnidirectional, random, and incoherent nature of photoluminescence (PL) emission, the multiplexing modulation of PL remains a challenge and is rarely realized. Here, a direction‐decoupled light‐emitting metasurface (LEM) is originally demonstrated to display dual‐channel independent incoherent‐emission images based on guided‐PL manipulation. Utilizing the wavevector differences of guided‐PL between opposite pumping directions, the LEM is designed to enable selective unidirectional emission, thereby decoupling the directional freedom for PL multiplexing and realizing dual meta‐display. Besides, the direction‐multiplexed LEM can be integrated simultaneously with pumping‐light holography for multi‐dimensional meta‐display. Such programmable unidirectional emission manipulation and direction‐multiplexed PL meta‐display approaches promise light‐emitting techniques and can potentially find applications in multiplexing display, optical storage and encryption, etc.

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Optical Information Encryption Based on Secret Sharing Liquid Crystal Elements with Spatial Dislocation

Xu,

Qiao,

Guo

et al. 2024

Laser & Photonics Reviews

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Optical encryption is an increasingly significant technique in the realm of information security. In the recent decade, there has been considerable interest in using planar optics elements for information encryption. However, information leakage possibly occurs due to limited encrytion channels available for single‐layer devices. To circumvent this problem, a novel encryption method is put forward using secret sharing cascaded liquid crystal (LC) elements with spatial dislocation, which can produce near‐field patterns and far‐field holographic images under different illumination conditions. Specifically, Malus's Law and its inherent one‐to‐four mapping of rotational degeneracy, along with the Pancharatnam‐Berry (PB) phase introduced by LC molecules, to achieve multi‐channel encryption are utilized. Therefore, each cascaded LC unit can manipulate the amplitude and phase imparted to output light independently, thus only by obtaining both LC devices can decryption be realized. To further enhance the encryption security, the author purposely divide each LC device into multiple regions and find that the encrypted patterns can only be recovered when the two LC elements align precisely with a specific dislocation. These experimental measurements agree well with the design, thus demonstrating the strong encryption capability and broad application prospects of the design approach in the field of optical encryption with high cost‐effectiveness.

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Compression-Encrypted Meta-Optics for Storage Efficiency and Security Enhancement

Cited by 4 publications

References 34 publications

Ultra‐High Secure Holographically Steganographic Array with Spatiotemporal Dual‐Encryption Keys

Ultra‐High Secure Holographically Steganographic Array with Spatiotemporal Dual‐Encryption Keys

Direction‐Decoupled Light‐Emitting Metasurface via Guided‐Photoluminescence Manipulation

Optical Information Encryption Based on Secret Sharing Liquid Crystal Elements with Spatial Dislocation

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