2024
DOI: 10.1002/adfm.202313498
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Design of Fatigue‐Resistant Hydrogels

Zilong Han,
Yuchen Lu,
Shaoxing Qu

Abstract: Hydrogels are made tough to resist crack propagation. However, for seamless integration into devices and machines, it necessitates robustness against cyclic loads. Central to this objective is enhancing fatigue resistance, an indispensable attribute facilitating the optimal performance of hydrogels within a multitude of biological contexts, spanning various plant and animal tissues, as well as diverse biomedical and engineering areas. In this review, recent research concerning the fatigue behavior of hydrogels… Show more

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Cited by 16 publications
(1 citation statement)
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“…These sensors are recognized for their valuable attributes, such as high stretchability, repeatability, low power consumption, and rapid response times. , Consequently, they are utilized in various sectors, including human health monitoring, thereby making notable contributions to advancements in this field. To enhance the functionality of sensors in wearable devices, researchers primarily concentrate on utilizing conductive nanomaterials and structural design to develop novel sensor components with superior attributes like flexibility, microminiaturization, composite functionality, and splicing assembly. Conductive nanocomposites offer advantages, such as a significant surface area, excellent electronic transmission properties, and fast electron transfer rates, thereby enabling prompt responses.…”
mentioning
confidence: 99%
“…These sensors are recognized for their valuable attributes, such as high stretchability, repeatability, low power consumption, and rapid response times. , Consequently, they are utilized in various sectors, including human health monitoring, thereby making notable contributions to advancements in this field. To enhance the functionality of sensors in wearable devices, researchers primarily concentrate on utilizing conductive nanomaterials and structural design to develop novel sensor components with superior attributes like flexibility, microminiaturization, composite functionality, and splicing assembly. Conductive nanocomposites offer advantages, such as a significant surface area, excellent electronic transmission properties, and fast electron transfer rates, thereby enabling prompt responses.…”
mentioning
confidence: 99%