用于太阳能光-芬顿催化的中空连接网络的增材制造。

Miguel Ángel Gracia-Pinilla, Norma Alicia Ramos-Delgado, Cristian Rosero-Arias, Remco Sanders, Stephan Bartling, Jędrzej Winczewski, Han Gardeniers, Arturo Susarrey-Arce
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引用次数: 0

摘要

采用三维打印方法制造绿色体/前驱体微体系结构,退火后可制造分层三维中空微体系结构(3DHM)。三维空心微体系结构主要由二氧化钛和无机稳定剂组成,在 650 ℃ 的热退火条件下可生成无机蜂窝单元。形态学检查显示,三维结构梁由二氧化钛纳米颗粒(NPs)组成。空心梁的内外直径分别为 ∼80 μm 和 ∼150 μm,在整个三维空心网络中保持不变。对概念验证的光-芬顿反应进行了评估。三维空心膜浸渍了 α-Fe2O3 NPs,以评估太阳能光-芬顿降解有机化合物的情况,如用作对照的甲基溴和有机污染物对乙酰氨基酚。通过对光学、结构和化学环境特征以及清除剂分析,我们深入了解了负载有 α-Fe2O3 的 TiO2 3DHMs 的拟议太阳能光-芬顿降解反应。我们的工作展示了具有互连网络的新型中空打印微体系结构,这有助于引导催化反应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Additive manufacturing of hollow connected networks for solar photo-Fenton-like catalysis.

A 3D-printing approach is used to fabricate green bodies/precursor microarchitectures that, upon annealing, allow the fabrication of hierarchical 3D hollow microarchitectures (3DHMs). The 3DHMs are composed mainly of TiO2 and inorganic stabilizers that enable the production of inorganic cellular units upon thermal annealing at 650 °C. Morphological inspection reveals that the 3D architecture beams comprise TiO2 nanoparticles (NPs). The inner and outer diameters of the hollow beams are ∼80 μm and ∼150 μm, retained throughout the 3D hollow network. A proof-of-concept photo-Fenton reaction is assessed. The 3DHMs are impregnated with α-Fe2O3 NPs to evaluate solar photo-Fenton degradation of organic compounds, such as MB used as control and acetaminophen, an organic pollutant. The optical, structural, and chemical environment characteristics, alongside scavenger analysis, generate insights into the proposed solar photo-Fenton degradation reaction over TiO2 3DHMs loaded with α-Fe2O3. Our work demonstrates newly hollow printed microarchitecture with interconnected networks, which can help direct catalytic reactions.

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