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Multiscale Design for Robust, Thermal Insulating, and Flame Self‐Extinguishing Cellulose Foam

Hao Sun, Dingyuan Zheng, Yeling Zhu, Penghui Zhu, Yuhang Ye, Yifan Zhang, Zhengyang Yu, Pu Yang, Xia Sun, Feng Jiang

2023Small50 citationsDOIOpen Access PDF

Abstract

Abstract Cellulose foams are in high demand in an era of prioritizing environmental consciousness. Yet, transferring the exceptional mechanical properties of cellulose fibers into a cellulose network remains a significant challenge. To address this challenge, an innovative multiscale design is developed for producing cellulose foam with exceptional network integrity. Specifically, this design relies on a combination of physical cross–linking of the microfibrillated cellulose (MFC) networks by cellulose nanofibril (CNF) and aluminum ion (Al 3+ ), as well as self‐densification of the cellulose induced by ice‐crystal templating, physical cross–linking, solvent exchange, and evaporation. The resultant cellulose foam demonstrates a low density of 40.7 mg cm –3 , a high porosity of 97.3%, and a robust network with high compressive modulus of 1211.5 ± 60.6 kPa and energy absorption of 77.8 ± 1.9 kJ m −3 . The introduction of CNF network and Al 3+ cross–linking into foam also confers excellent wet stability and flame self‐extinguish ability. Furthermore, the foam can be easily biodegraded in natural environments , re‐entering the ecosystem's carbon cycle. This strategy yields a cellulose foam with a robust network and outstanding environmental durability, opening new possibilities for the advancement of high‐performance foam materials.

Topics & Concepts

CelluloseMaterials scienceComposite materialPorosityThermal stabilityCarbon nanofoamChemical engineeringEngineeringAdvanced Cellulose Research StudiesAerogels and thermal insulationFlame retardant materials and properties