材料科学
3D打印
碳纤维
碳捕获和储存(时间表)
纳米技术
复合材料
化学工程
工程制图
复合数
生态学
生物
工程类
气候变化
作者
Kunhao Yu,Teng Teng,So Hee Nah,Hua Chai,Yefan Zhi,Kunyu Wang,Yinding Chi,Peter Psarras,Masoud Akbarzadeh,Shu Yang
标识
DOI:10.1002/adfm.202509259
摘要
Abstract Concrete, the world's second most utilized material after water, is responsible for 8% of global greenhouse emissions. Current carbon capturing and storage (CCS) concrete often involves convoluted processes, slow kinetics, limited CO 2 uptake, non‐uniform carbonation in structures, and high cost. Efforts to enhance carbon sequestration often rely on increasing porosities, which compromise the mechanical strength of the resulting concrete. The 3D printing of CCS concrete is reported by incorporating diatomaceous earth (DE), a highly accessible biomineral with hierarchical porosity, into triply periodic minimal surface (TPMS) structures. DE enables stable extrusion, high print fidelity, and reduced density, which are crucial for 3D concrete printing. Further, DE facilitates CaCO 3 nucleation within the concrete and mitigates carbonation resistance, achieving a maximum CO 2 absorption of 488.7 gCO 2 per kg cement in 7 days, a 142% increase over conventional concrete. Optimizing TPMS geometry further enhances carbonation efficiency by enabling uniform CO 2 uptake throughout the structure. This geometry refinement reduces material usage by 78% and increases the surface‐area‐to‐volume ratio by 515%, leading to a 30% higher CO 2 uptake while preserving mechanical integrity. The material strategy, together with the optimized concrete printing of TPMS structures, offers a pathway toward scalable and sustainable solutions without undermining concrete's structural functions.
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