Muscle-inspired formable wood-based phase change materials

Muscle-inspired formable wood-based phase change materials

Phase change materials (PCMs) are crucial for sustainable thermal management in energy-efficient construction and cold chain logistics, as they can store and release renewable thermal energy. However, traditional PCMs suffer from leakage and a loss of formability above their phase change temperature...

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Bibliographic Details
Main Authors: Liu, Yifan, Lv, Zhisheng, Zhou, Jiazuo, Cui, Zequn, Li, Wenlong, Yu, Jing, Chen, Lixun, Wang, Xin, Wang, Meng, Liu, Kunyang, Wang, Hui, Ji, Xinyao, Hu, Senwei, Li, Jian, Loh, Xian Jun, Yang, Haiyue, Chen, Xiaodong, Wang, Chengyu
Other Authors: School of Materials Science and Engineering
Format: Article
Language:English
Published: 2024
Subjects:
Engineering
Sustainable materials
Wood gels
Online Access:https://hdl.handle.net/10356/180808
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Institution: Nanyang Technological University
Language: English
Description
Summary:Phase change materials (PCMs) are crucial for sustainable thermal management in energy-efficient construction and cold chain logistics, as they can store and release renewable thermal energy. However, traditional PCMs suffer from leakage and a loss of formability above their phase change temperatures, limiting their shape stability and versatility. Inspired by the muscle structure, formable PCMs with a hierarchical structure and solvent-responsive supramolecular networks based on polyvinyl alcohol (PVA)/wood composites are developed. The material, in its hydrated state, demonstrates low stiffness and pliability due to the weak hydrogen bonding between aligned wood fibers and PVA molecules. Through treatment of poly(ethylene glycol) (PEG) into the PVA/wood PEG gel (PEG/PVA/W) with strengthened hydrogen bonds, the resulting wood-based PCMs in the hard and melting states elevate the tensile stress from 10.14 to 80.86 MPa and the stiffness from 420 MPa to 4.8 GPa, making it 530 times stiffer than the PEG/PVA counterpart. Capable of morphing in response to solvent changes, these formable PCMs enable intricate designs for thermal management. Furthermore, supported by a comprehensive life cycle assessment, these shape-adaptable, recyclable, and biodegradable PCMs with lower environmental footprint present a sustainable alternative to conventional plastics and thermal management materials.

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