延伸率
脆性
生物量(生态学)
材料科学
延展性(地球科学)
纤维素
复合材料
纳米纤维
压力(语言学)
抗压强度
极限抗拉强度
化学工程
蠕动
工程类
地质学
哲学
海洋学
语言学
作者
Yuqing Chang,Yichen Tian,Jiacheng Wang,Jingyi Zhao,Lei Chen,Shuhua Kang,Qiang Lu,Xiaodong He,Qiang Zhang
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2025-08-01
卷期号:11 (31): eady0746-eady0746
被引量:8
标识
DOI:10.1126/sciadv.ady0746
摘要
Biomass-based foams present a promising alternative to conventional plastic foams. However, many reported biomass-based foams are composed of nondegradable components and are mechanically weak and brittle. We proposed a hybrid biomass-driven foaming strategy that used specially designed cellulose nanofibers and sodium caseinate to synergistically create stable wet foams and form gas-impermeable bubble interfaces to prevent structural collapse during oven drying. The foams exhibited high tensile stress (~400 kPa) comparable to that of brittle foams and had excellent ductility, with an elongation of 137.0%. The foams also displayed outstanding cyclic elastic behavior, retaining more than 90% of their compressive stress after 100 cycles. In addition, the foams were water-weldable, recovering 87.3% of their original tensile stress and nearly 100% of their elongation, allowing them to be tailored into customized geometric structures. A roll-to-roll casting process was used to produce continuous foam rolls, demonstrating successful scalability. This study provides an advanced formulation for fabricating fully degradable biomass-based foams with superior mechanical properties.
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