Exploiting enzymes to optimize the pH-universal electrocatalytic ORR performance of biomass-based nanoporous carbons

To obtain high-performance biomass-based electrocatalysts, pore formation and heteroatom doping into biochar backbones are required. Because of the dense and ductile lignocellulosic structures of plant biomass, it is challenging for chemical additives to effectively infiltrate fabrics and tissues. L...

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Bibliographic Details
Published in:New journal of chemistry 2023-07, Vol.47 (28), p.13193-1324
Main Authors: Wang, Huifen, Kong, Xiao, Zhang, Wendu, Bai, Peiyao, Yang, Chuangchuang, Liu, Weiqi, Wei, Shilin, Xu, Lang
Format: Article
Language:English
Subjects:
Additives
Biomass
Cellulase
Doping
Electrocatalysts
Enzymes
Hemicellulases
Lignocellulose
Pore formation
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Summary:To obtain high-performance biomass-based electrocatalysts, pore formation and heteroatom doping into biochar backbones are required. Because of the dense and ductile lignocellulosic structures of plant biomass, it is challenging for chemical additives to effectively infiltrate fabrics and tissues. Loosening these lignocellulosic frameworks holds the key to improved performance. In this work, hemicellulase and cellulase are used to act on staple forestry waste, leading to partial hydrolysis of lignocellulosic frameworks of biomass. The enzymatic modification gives rise to the enlargement of pore space in the biomass, which is made readily accessible to chemical additives and therefore results in increased efficiencies of nanopore formation and nitrogen doping. Consequently, biomass-based nanoporous carbons treated with enzymes show superior pH-universal electrocatalytic ORR performance compared to those without enzymatic processing. This work enriches the electrocatalysis field with biomass utilization methods and gives us fresh perspectives on nanoporous modulation. Enzymatic modification loosens lignocellulosic frameworks, leading to the enlargement of pore space in the biomass, which is made readily accessible to extrinsic chemicals for efficient pore formation and heteroatom doping.
ISSN:1144-0546
1369-9261
DOI:10.1039/d3nj01480k