Cellulose Functional Gels: Physical Design and Promising Applications DOI Creative Commons

Minxin Wang,

Geyuan Jiang, Xiaoyu Guo

et al.

Advanced Physics Research, Journal Year: 2025, Volume and Issue: unknown

Published: May 6, 2025

Abstract Cellulose gels, including ionic hydrogels, and aerogels, are 3D, soft polymeric materials known for their excellent properties designability. As sustainability green chemistry gain prominence, performance improvement functional design of cellulose gels have attracted growing attention. The macroscopic physical can be shaped by constructing a gel network, which regulated methods such as freezing, force induction, heat treatment to adjust the mechanical properties, transparency, thermal stability cellulose. Additionally, structural self‐assembly at molecular level endow with diverse functions, stretchability, high toughness, conductivity, self‐healing ability. These characteristics give them broad application potential in biomedicine, flexible electronics, adsorption, food engineering. This article delves into fundamental concepts, design, enhancement methods, strategies, trending applications cellulose‐based across various fields. It provides comprehensive overview this promising material offers insights guidance future research development.

Language: Английский

Cellulose Functional Gels: Physical Design and Promising Applications DOI Creative Commons

Minxin Wang,

Geyuan Jiang, Xiaoyu Guo

et al.

Advanced Physics Research, Journal Year: 2025, Volume and Issue: unknown

Published: May 6, 2025

Abstract Cellulose gels, including ionic hydrogels, and aerogels, are 3D, soft polymeric materials known for their excellent properties designability. As sustainability green chemistry gain prominence, performance improvement functional design of cellulose gels have attracted growing attention. The macroscopic physical can be shaped by constructing a gel network, which regulated methods such as freezing, force induction, heat treatment to adjust the mechanical properties, transparency, thermal stability cellulose. Additionally, structural self‐assembly at molecular level endow with diverse functions, stretchability, high toughness, conductivity, self‐healing ability. These characteristics give them broad application potential in biomedicine, flexible electronics, adsorption, food engineering. This article delves into fundamental concepts, design, enhancement methods, strategies, trending applications cellulose‐based across various fields. It provides comprehensive overview this promising material offers insights guidance future research development.

Language: Английский

Citations

0