陶瓷
材料科学
复合材料
微观结构
多孔性
纳米颗粒
硅酸盐
硅酸钙
抗压强度
耐久性
水合硅酸钙
复合数
工程木材
可再生资源
碳酸钙
纳米材料
碳纤维
热解
热的
作者
Fengyin Du,Yanpei Tian,Zhenyuan Niu,Kangyi Cai,Junyi Duan,Haoran Guo,Ruizhe Yang,Y Zhang,Jazmine Aiya Marquez,Haoyu Zeng,Xiaojie Liu,Qingsheng Wang,Chengcheng Tao,Hongyan Ma,Tian Li
标识
DOI:10.1038/s41467-026-73601-3
摘要
Increasingly extreme environmental conditions demand structural materials that combine mechanical robustness with sustainability. Natural wood is renewable and mechanically adaptable but suffers from high porosity and hydrophilicity, leading to moisture absorption, fire vulnerability, and environmental degradation. Ceramics provide high stiffness, thermal stability, and chemical resistance but are inherently brittle. Here we report ceramic wood, a composite formed by integrating a natural wood scaffold with uniformly distributed ceramic nanoparticles. A calcium silicate precursor infiltrates the aligned nanofluidic channels of wood and undergoes in-situ self-assembly into calcium silicate hydrate nanoparticles under room-temperature conditions. The resulting ceramic network fills micropores and forms strong interfacial bonding within the wood scaffold. Ceramic wood exhibits high compressive strength, enhanced toughness, excellent fire resistance, and improved durability against moisture, fungi attack, and alkaline environments. CO₂ uptake further reduces the carbon footprint, highlighting ceramic wood as a sustainable structural material for extreme environments. Silicified woods have potential as environmentally friendly, fire-resistant building materials. Here, the authors report a process in which calcium silicate uniformly self assembles within wood’s microstructure, yielding high strength ceramic-wood composites with good fire resistance and environmental stability.
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