光催化
纳米棒
材料科学
氢氧化物
催化作用
微尺度化学
化学工程
氧化物
铟
纳米技术
化学
有机化学
光电子学
数学教育
冶金
工程类
数学
作者
Lourdes Hurtado,Abhinav Mohan,Ulrich Ulmer,Reyna Natividad,Athanasios A. Tountas,Wei Sun,Lu Wang,Boeun Kim,Mohini Sain,Geoffrey A. Ozin
标识
DOI:10.1016/j.cej.2022.134864
摘要
Here we report the enhanced light penetration and mass transfer efficiency of photocatalytic foams to convert CO2 to CO. The viability of utilizing a metallic foam as a model photocatalyst support is used to evaluate the photochemical and thermochemical reverse water gas shift reaction catalyzed by photoactive indium oxide hydroxide nanorods uniformly coated on nickel foams. A light-enhanced CO production rate up to 130% higher than the dark CO production was achieved through enhanced light penetration. A remarkably high thermochemical CO production rate of 0.75 mmol gcat−1 h−1 was achieved at 295 °C. Whilst several approaches to optimization of photocatalyst morphology at the nanoscale have been successful in extending electron hole-pair lifetime and modifying the site of reactions, these advantages cannot be significantly realized unless microscale to macroscale structuring efforts, that shorten the path length for diffusion of the reactant gas molecule and lengthen photon penetration to these catalytic sites are integrated. The superior catalytic performance of the indium oxide hydroxide nanorods on an optimized coated foam configuration compared to the performance of packed bed and thin film configurations demonstrates the critical importance of using structured supports in scale up of future photocatalytic processes.
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