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Retrievable Hierarchically Porous Ferroelectric Ceramics for “Greening” the Piezo‐Catalysis Process

Hanyu Gong, Yan Zhang, Jingjing Ye, Xiang Zhou, Xuefan Zhou, Yan Zhao, Kaiyu Feng, Hang Luo, Dou Zhang, Chris Bowen

2024Advanced Functional Materials35 citationsDOIOpen Access PDF

Abstract

Abstract Powder‐based piezo‐catalysis, as an effective approach to degrade wastewater and produce hydrogen from water splitting, has been widely used in the field of energy conservation and pollution reduction. However, these hard‐to‐recycle powders pose a challenge of secondary pollution in the environment. As a result, this paper provides an alternative strategy based on the manufacture of porous ceramics as a green chemistry approach to replace ferroelectric powders currently used in traditional piezo‐catalysis. The piezo‐catalytic properties of Ba 0.75 Sr 0.25 TiO 3 (BST) ceramics prepared using freeze casting and direct ink writing techniques are investigated in detail. The positive effect of introducing micro‐ and macro‐pores is explored and discovered, where a BST ceramic with hierarchical pore channels is prepared by a combination of direct ink writing and freeze casting and exhibts the highest first‐order kinetic rate constant per mass of catalysts, k , of up to 2.91 min −1 kg −1 compared to bulk BST ceramics. This study therefore provides the first report for the benefits of hierarchical porous ferroelectric ceramics used in water splitting, with an average H 2 production rate reaching 848.88 nmol g −1 h −1 .

Topics & Concepts

Materials scienceCeramicCatalysisPorosityFerroelectricityCastingInkwellChemical engineeringEnvironmental pollutionNanotechnologyTape castingComposite materialOrganic chemistryOptoelectronicsEnvironmental scienceDielectricChemistryEngineeringEnvironmental protectionAdvanced Photocatalysis TechniquesCovalent Organic Framework Applications
Retrievable Hierarchically Porous Ferroelectric Ceramics for “Greening” the Piezo‐Catalysis Process | Litcius