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Self‐Sustained Programmable Hygroelectronic Interfaces for Humidity‐Regulated Hierarchical Information Encryption and Display

The emerging moisture‐driven energy generation (MEG) technology opens up new possibilities for humidity‐responsive materials, devices, and interdisciplinary opportunities in fields like information security. However, such potential remains untapped. Here, an original MEG structure with a hygroionic...

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Published in:	Advanced materials (Weinheim) 2024-03, Vol.36 (12), p.e2208081-n/a
Main Authors:	Zhang, Yaoxin, Yu, Zhen, Qu, Hao, Guo, Shuai, Yang, Jiachen, Zhang, Songlin, Yang, Lin, Cheng, Shaoan, Wang, John, Tan, Swee Ching
Format:	Article
Language:	English
Subjects:	Carbon Carbon black encryption and display Humidity Hydrogels hygroelectronic structures Hygroscopicity information platforms moisture‐driven energy generation Morse code Route selection Security self‐powered electronics
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cited_by	cdi_FETCH-LOGICAL-c3731-11455f000c506e14eb397c2852b1a9244a51d1ecaaf4fda56cca35c7426347273
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creator	Zhang, Yaoxin Yu, Zhen Qu, Hao Guo, Shuai Yang, Jiachen Zhang, Songlin Yang, Lin Cheng, Shaoan Wang, John Tan, Swee Ching
description	The emerging moisture‐driven energy generation (MEG) technology opens up new possibilities for humidity‐responsive materials, devices, and interdisciplinary opportunities in fields like information security. However, such potential remains untapped. Here, an original MEG structure with a hygroionic energy‐conversion route by selective coating of ionic hygroscopic hydrogels on a carbon black surface is reported. The hygroionic route features a process in which the scavenged energy is stored in the electrical double layers formed at the interfaces between the ionic hydrogel and the carbon nanoparticles. The resultant electrical field developed across the hydrogel‐coated wet carbon and the rest of the dry carbon area is thus durably lasted. Based on this unique structure, hygroelectronic information interfaces (HEII) for humidity‐regulated information encryption and display are put forward by devising hydrogel patterns on a carbon platform. Further by tuning the hygroscopicity of the ionic hydrogels and incorporating encoding methods (e.g., Morse code), it is demonstrated that the HEII platform is programmable to carry different information in certain humidity ranges. Unlike those conventional anti‐counterfeiting methods that optically reveal the hidden information once the required stimulus is provided, the new HEII serves as a hierarchical solution for high‐security encryption and display. The emerging moisture‐driven energy generation (MEG) technology opens up new possibilities for humidity‐responsive materials, devices, and interdisciplinary opportunities in fields like information security. Here, hygroelectronic information interfaces, which are based on an MEG structure with a hygroionic energy‐conversion route, are put forward for humidity‐regulated hierarchical information encryption and display.
doi_str_mv	10.1002/adma.202208081
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However, such potential remains untapped. Here, an original MEG structure with a hygroionic energy‐conversion route by selective coating of ionic hygroscopic hydrogels on a carbon black surface is reported. The hygroionic route features a process in which the scavenged energy is stored in the electrical double layers formed at the interfaces between the ionic hydrogel and the carbon nanoparticles. The resultant electrical field developed across the hydrogel‐coated wet carbon and the rest of the dry carbon area is thus durably lasted. Based on this unique structure, hygroelectronic information interfaces (HEII) for humidity‐regulated information encryption and display are put forward by devising hydrogel patterns on a carbon platform. Further by tuning the hygroscopicity of the ionic hydrogels and incorporating encoding methods (e.g., Morse code), it is demonstrated that the HEII platform is programmable to carry different information in certain humidity ranges. Unlike those conventional anti‐counterfeiting methods that optically reveal the hidden information once the required stimulus is provided, the new HEII serves as a hierarchical solution for high‐security encryption and display. The emerging moisture‐driven energy generation (MEG) technology opens up new possibilities for humidity‐responsive materials, devices, and interdisciplinary opportunities in fields like information security. 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Unlike those conventional anti‐counterfeiting methods that optically reveal the hidden information once the required stimulus is provided, the new HEII serves as a hierarchical solution for high‐security encryption and display. The emerging moisture‐driven energy generation (MEG) technology opens up new possibilities for humidity‐responsive materials, devices, and interdisciplinary opportunities in fields like information security. 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subjects	Carbon Carbon black encryption and display Humidity Hydrogels hygroelectronic structures Hygroscopicity information platforms moisture‐driven energy generation Morse code Route selection Security self‐powered electronics
title	Self‐Sustained Programmable Hygroelectronic Interfaces for Humidity‐Regulated Hierarchical Information Encryption and Display
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