Multidimensional‐Encryption in Emissive Liquid Crystal Elastomers through Synergistic Usage of Photorewritable Fluorescent Patterning and Reconfigurable 3D Shaping

Gao, Jingjing; Tian, Meng; He, Yan-Rong; Yi, Huijie; Guo, Jinbao

doi:10.1002/adfm.202107145

Cited by 59 publications

(38 citation statements)

References 59 publications

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“…For example, the use of improper "ink" may induce nonadjustable information-recording times, and the lack of encryption and decryption modes restrict the usage of the information-related materials. [15] Moreover, the demand for information storage materials with apparent recording capacities, high-security performances, and long-term and repeatable "writing" properties has increased. [16,17] Recently, stimulus-responsive hydrogels, that can undergo reversible volume or color changes upon triggering via external stimuli, such as pH, temperature, light, magnetic fields, and ionic concentrations, have attracted tremendous attention.…”

Section: Introductionmentioning

confidence: 99%

“…For example, the use of improper “ink” may induce nonadjustable information‐recording times, and the lack of encryption and decryption modes restrict the usage of the information‐related materials. [ 15 ] Moreover, the demand for information storage materials with apparent recording capacities, high‐security performances, and long‐term and repeatable “writing” properties has increased. [ 16,17 ]…”

Section: Introductionmentioning

confidence: 99%

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Paper‐Structure Inspired Multiresponsive Hydrogels with Solvent‐Induced Reversible Information Recording, Self‐Encryption, and Multidecryption

Chen

Guo

et al. 2022

Adv Funct Materials

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Information recording and encryption/decryption functions are essential due to the prevalence of counterfeiting activities and information leakage in the current age. However, the development of high-resolution information recording and multistage information protection systems to achieve high data security levels, such as self-erasing encrypted data and time-controlled data handling, remains limited. Herein, inspired by the information-recording structure of paper, a multiresponsive nanofiber-reinforced poly(N-isopropylacrylamide) (PNIPAM) hydrogel (NCPN hydrogel) with improved mechanical properties, solvent-induced high-resolution reversible information recording, self-encryption, and multi-decryption capabilities, is proposed. Due to the unique hydrophilic and hydrophobic structures of the hydrogel matrix, ethanol and other polar analogs can be applied as special inks to record information by changing the lower critical solution temperature to achieve the repeatable transmittance variation. The recorded information can be erased via water wiping or ethanol volatilization. Additionally, self-encryption can be achieved and adjusted based on the ethanol volatilization time and concentration difference, and confidential information can be further decrypted in a water environment or under a thermal stimulus. Furthermore, several stable, repeatable, and fast-response hydrogel-based information-recognition systems are designed and investigated. Therefore, the designed hydrogel-based informational platform provides a universal information-handling system allowing for the reversible recording of information, with self-encryption and multidecryption capabilities.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Paper‐Structure Inspired Multiresponsive Hydrogels with Solvent‐Induced Reversible Information Recording, Self‐Encryption, and Multidecryption

Chen

Guo

et al. 2022

Adv Funct Materials

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show abstract

Section: Introductionmentioning

confidence: 99%

“…Except for magnetic developers, fluorescent powders are also commonly used for fingerprint visualization based on their strong light absorption capacity and continuous luminous, especially for excellent optical storage capability and signal transmission features. 16,22 In general, fluorescent developers can be categorized four types: quantum dots, 23,24 fluorescent carbon dots, 25,26 metal nanomaterials (e.g., Au, Ag nanoparticles), 27,28 and rare earth luminescent nanomaterials. [29][30][31] Among them, rare earth luminescent materials possess the merits of high photochemical stability, reduced photo bleaching, lowtoxicity, high contrast and high resolution, and thus they are considered as good candidates for latent fingerprint visualization.…”

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confidence: 99%

Versatile core–shell magnetic fluorescent mesoporous microspheres for multilevel latent fingerprints magneto‐optic information recognition

Liu

Xie

et al. 2022

InfoMat

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Latent fingerprints are extremely vital for personal identification and criminal investigation, and potential information recognition techniques have been widely used in the fields of information and communication electronics. Although physical powder dusting methods have been frequently employed to develop latent fingerprints and most of them are carried out by using single component powders of micron‐sized fluorescent particles, magnetic powders, or metal particles, there is still an enormous challenge in producing high‐resolution image of latent fingerprints at different backgrounds or substrates. Herein, a novel and effective nanoimpregnation method is developed to synthesize bifunctional magnetic fluorescent mesoporous microspheres for latent fingerprints visualization by growth of mesoporous silica (mesoSiO2) on magical Fe3O4 core and then deposition of fluorescent YVO4:Eu3+ nanoparticles in the mesopores. The obtained Fe3O4@mesoSiO2@YVO4:Eu3+ microspheres possess spatially isolated magnetic core and fluorescent shell which were insulated by mesoporous silica layer. Due to their small particle size of submicrometer scale, high magnetization and low magnetic remanence as well as the combined magnetic and fluorescent properties, the microspheres show superior performance in visual latent fingerprint recognition with high contrast, high anti‐interference, and sensitivity as well as good retention on multifarious substrates regardless of surface permeability, roughness, refraction, colorfulness, and background fluorescence interference, and it makes them ideal candidates for practical application in fingerprint visualization and even magneto‐optic information storage.

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confidence: 99%

Integrating Photorewritable Fluorescent Information in Shape‐Memory Organohydrogel Toward Dual Encryption

Shang

Sun

et al. 2022

Advanced Optical Materials

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information, the ability to encrypt information has more important significance in information security. Nowadays, many scientists focus on the development of latemodel anti-counterfeiting materials, and corresponding strategies, [1][2][3][4] including bar code, two-dimensional code, holograms, luminous materials, and so on. Among them, luminous materials can be one of the best candidates for anti-counterfeiting due to their responsiveness to UV light, [5,6] the diversity of vivid colors [7,8] as well as various luminescence modes. [9,10] Given the excellent modifiability, containment and unique stimulus-responsiveness of polymeric hydrogels, [11][12][13][14] the combination of luminescence materials and intelligent hydrogels can make the stored information dynamic and improve security level. Up to now, a large number of studies have focused on information storage or information encryption [15][16][17][18] on the basis of fluorescent hydrogels. For example, Ji's group [19] fabricated a self-assemble hydrogel with polyvinyl alcohol (PVA) hydrogel doping three kinds of aggregation induced emission (AIE) fluorescent monomers. The prepared multi fluorescent hydrogel could store a large amount of information by introducing 1D barcodes or 2D codes and arraying the fluorescent blocks. Saunders and coworkers [20] employed microgels (MG) as As one of the severe global problems, counterfeiting information has brought a huge negative impact on every aspect of human society. Though various anticounterfeiting strategies, including fluorescent materials, are widely developed for dealing with the above problem, the information security level needs to be further improved due to sophisticated hacking techniques. In this study, an organohydrogel is designed by constructing interpenetrating organohydrogel networks, in which naphthalimide moieties (DEAN, greenyellow emission) are introduced in hydrophilic poly(N,N-dimethylacrylamide) (PDMA) hydrogel network and anthracene units (blue emission) are copolymerized in hydrophobic polystearate methacrylate (PSMA) organogel network. Triggered by UV light of 365 nm, the unimer-dimer transition occurs and leads the fluorescent color of organohydrogel to change from blue to faint yellow, making secret information be stored with the assistance of photomasks. Furthermore, by combining crystallization-induced shape memory performance, dual encryption can be achieved. This fluorescent organohydrogel provides a new idea for fabricating smart materials with the ability of encryption-decryption, which is of great significance in information security protection.

show abstract

Multidimensional‐Encryption in Emissive Liquid Crystal Elastomers through Synergistic Usage of Photorewritable Fluorescent Patterning and Reconfigurable 3D Shaping

Cited by 59 publications

References 59 publications

Paper‐Structure Inspired Multiresponsive Hydrogels with Solvent‐Induced Reversible Information Recording, Self‐Encryption, and Multidecryption

Paper‐Structure Inspired Multiresponsive Hydrogels with Solvent‐Induced Reversible Information Recording, Self‐Encryption, and Multidecryption

Versatile core–shell magnetic fluorescent mesoporous microspheres for multilevel latent fingerprints magneto‐optic information recognition

Integrating Photorewritable Fluorescent Information in Shape‐Memory Organohydrogel Toward Dual Encryption

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