Rapid fabricated in-situ polymerized lignin hydrogel sensor with highly adjustable mechanical properties

Conductive hydrogels have been widely used as sensors owing to their tissue-like properties. However, the synthesis of conductive hydrogels with highly adjustable mechanical properties and multiple functions remains difficult to achieve yet highly needed. In this study, lignin hydrogel characterized...

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Veröffentlicht in:	International journal of biological macromolecules 2024-03, Vol.260 (Pt 2), p.129378-129378, Article 129378
Hauptverfasser:	Yang, Yutong, Zhu, Yachong, Yang, An, Liu, Tian, Fang, Yiqun, Wang, Weihong, Song, Yongming, Li, Yao
Format:	Artikel
Sprache:	eng
Schlagworte:	Acrylic acid Conductive hydrogel Electric Conductivity Humans Hydrogels Lignin Polymerization Quinones Sensor ZnCl2
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container_end_page	129378
container_issue	Pt 2
container_start_page	129378
container_title	International journal of biological macromolecules
container_volume	260
creator	Yang, Yutong Zhu, Yachong Yang, An Liu, Tian Fang, Yiqun Wang, Weihong Song, Yongming Li, Yao
description	Conductive hydrogels have been widely used as sensors owing to their tissue-like properties. However, the synthesis of conductive hydrogels with highly adjustable mechanical properties and multiple functions remains difficult to achieve yet highly needed. In this study, lignin hydrogel characterized by frost resistance, UV resistance, high conductivity, and highly adjustable mechanical properties without forming by-products was prepared through a rapid in-situ polymerization of acrylic acid/zinc chloride (AA/ZnCl2) aqueous solution containing lignin extract induced by the reversible quinone–catechol redox of the ZnCl2–lignin system at room temperature. Results revealed that the PAA/ZnCl2/lignin hydrogel exhibited mechanical properties with tensile stress (ranging from 0.08 to 3.28 MPa), adhesion to multiple surfaces (up to 62.05 J m−2), excellent frost resistance (−70–20 °C), UV resistance, and conductivity (0.967 S m−1), which further endow the hydrogel as potential strain and temperature sensor with wide monitor range (0–300 %), fatigue resistance, and quick response (70 ms for 150 % strain). This study proposed and developed a green, simple, economical, and efficient processing method for a hydrogel sensor in flexible wearable devices and man-machine interaction fields.
doi_str_mv	10.1016/j.ijbiomac.2024.129378
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However, the synthesis of conductive hydrogels with highly adjustable mechanical properties and multiple functions remains difficult to achieve yet highly needed. In this study, lignin hydrogel characterized by frost resistance, UV resistance, high conductivity, and highly adjustable mechanical properties without forming by-products was prepared through a rapid in-situ polymerization of acrylic acid/zinc chloride (AA/ZnCl2) aqueous solution containing lignin extract induced by the reversible quinone–catechol redox of the ZnCl2–lignin system at room temperature. Results revealed that the PAA/ZnCl2/lignin hydrogel exhibited mechanical properties with tensile stress (ranging from 0.08 to 3.28 MPa), adhesion to multiple surfaces (up to 62.05 J m−2), excellent frost resistance (−70–20 °C), UV resistance, and conductivity (0.967 S m−1), which further endow the hydrogel as potential strain and temperature sensor with wide monitor range (0–300 %), fatigue resistance, and quick response (70 ms for 150 % strain). 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However, the synthesis of conductive hydrogels with highly adjustable mechanical properties and multiple functions remains difficult to achieve yet highly needed. In this study, lignin hydrogel characterized by frost resistance, UV resistance, high conductivity, and highly adjustable mechanical properties without forming by-products was prepared through a rapid in-situ polymerization of acrylic acid/zinc chloride (AA/ZnCl2) aqueous solution containing lignin extract induced by the reversible quinone–catechol redox of the ZnCl2–lignin system at room temperature. Results revealed that the PAA/ZnCl2/lignin hydrogel exhibited mechanical properties with tensile stress (ranging from 0.08 to 3.28 MPa), adhesion to multiple surfaces (up to 62.05 J m−2), excellent frost resistance (−70–20 °C), UV resistance, and conductivity (0.967 S m−1), which further endow the hydrogel as potential strain and temperature sensor with wide monitor range (0–300 %), fatigue resistance, and quick response (70 ms for 150 % strain). 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subjects	Acrylic acid Conductive hydrogel Electric Conductivity Humans Hydrogels Lignin Polymerization Quinones Sensor ZnCl2
title	Rapid fabricated in-situ polymerized lignin hydrogel sensor with highly adjustable mechanical properties
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