材料科学
吸附
多孔性
大孔隙
萃取(化学)
化学工程
纳米技术
多孔介质
纤维
传质
微尺度化学
气凝胶
动力学
共价键
焊剂(冶金)
铀
大规模运输
压缩(物理)
复合数
整体
聚合物
混合材料
科技与社会
结构材料
作者
Yuxian Yang,Binbin Fan,Yang Si,Jianyong Yu,Peixin Tang
标识
DOI:10.1021/acsapm.5c03517
摘要
Oceans hold vast uranium (U) resources, while extraction is severely challenged by the ultralow U concentration and abundant competing ions. Covalent organic frameworks (COFs) offer promise due to their tunable functional groups and photocatalytic activity for U reduction. However, conventional COF materials face significant limitations, such as micropore-induced mass transfer resistance and impractical powder recycling. To overcome these challenges, we engineered biomimetic superadsorptive COF aerogels (SACAs) with biomimetic slit-shaped pores via a bubble-assisted bidirectional ice-templating methodology. This unique approach, involving dynamic regulation of the gas–liquid interface, constructs a hierarchically porous material featuring micro/mesopores for abundant active sites and interconnected macropores for rapid mass transport. The resulting SACA exhibits an ultralow density (11.2 mg/cm3), high elasticity, and exceptional underwater stability (withstanding >500 compression cycles). Critically, the biomimetic slit-shaped porous structure inherent to this design provides superior fluid transport kinetics and an ultrahigh equilibrium adsorption capacity (1776.86 mg/g) under visible light irradiation. In the dynamic adsorption test, the SACA exhibited a constant extraction capacity under varied flux rates, alongside excellent recyclability and outstanding adsorption selectivity. The successful development of such materials with biomimetic slit-shaped pores will drive innovation in environmental, energy, and electronic applications, showcasing promising prospects for practical applications.
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