{"database":"biostudies-literature","file_versions":[],"scores":null,"additional":{"submitter":["Guo J"],"funding":["the Innovation and Entrepreneurship Training Program for College Students","the Research start-up fund project for high-level talents of Moutai University","Modern Baijiu Brewing Technology Engineering Research Center of Guizhou Universities","Guizhou Province Technology Innovation Center for Jiangxiangxing Baijiu"],"pagination":["1530"],"full_dataset_link":["https://www.ebi.ac.uk/biostudies/studies/S-EPMC12526432"],"repository":["biostudies-literature"],"omics_type":["Unknown"],"volume":["15(19)"],"pubmed_abstract":["To address the challenges of complex composition, high chemical oxygen demand (COD) content, and the difficulty of treating organic wastewater from brewery wastewater, as well as the limitations of traditional Fenton technology, including low catalytic activity and high material costs, this study proposes the use of biochemical sludge as a raw material. Coupled with iron salt activation and mechanical ball milling technology, a low-cost, high-performance iron-doped mesoporous nano-sludge biochar material is prepared. This material was employed as a particle electrode to construct a three-dimensional electro-Fenton system for the degradation of organic wastewater from sauce-flavor liquor brewing. The results demonstrate that the sludge-based biochar produced through this approach possesses a mesoporous structure, with an average particle size of 187 nm, a specific surface area of 386.28 m<sup>2</sup>/g, and an average pore size of 4.635 nm. Iron is present in the material as multivalent iron ions, which provide more electrochemical reaction sites. Utilizing response surface methodology, the optimized treatment process achieves a maximum COD degradation rate of 71.12%. Compared to the control sample, the average particle size decreases from 287 μm to 187 nm, the specific surface area increases from 44.89 m<sup>2</sup>/g to 386.28 m<sup>2</sup>/g, and the COD degradation rate improves by 61.1%. Preliminary investigations suggest that the iron valence cycle (Fe<sup>2+</sup>/Fe<sup>3+</sup>) and the mass transfer enhancement effect of the mesoporous nano-structure are keys to efficient degradation. The Fe-O-Si structure enhances material stability, with a degradation capacity retention rate of 88.74% after 30 cycles of use. When used as a particle electrode to construct a three-dimensional electro-Fenton system, this material demonstrates highly efficiency in organic matter degradation and shows promising potential for application in the treatment of organic wastewater from sauce-flavor liquor brewing."],"journal":["Nanomaterials (Basel, Switzerland)"],"pubmed_title":["Iron -Doped Mesoporous Nano-Sludge Biochar via Ball Milling for 3D Electro-Fenton Degradation of Brewery Wastewater."],"pmcid":["PMC12526432"],"funding_grant_id":["Qiankehe Platform JSZX (2025) 002","202314625011","MYGCCRC(2022)001","Qianjiaoji [2023] No. 028"],"pubmed_authors":["Guo J","Xie Y","Shi W","Shi T","Wu F","Liu W"],"additional_accession":[]},"is_claimable":false,"name":"Iron -Doped Mesoporous Nano-Sludge Biochar via Ball Milling for 3D Electro-Fenton Degradation of Brewery Wastewater.","description":"To address the challenges of complex composition, high chemical oxygen demand (COD) content, and the difficulty of treating organic wastewater from brewery wastewater, as well as the limitations of traditional Fenton technology, including low catalytic activity and high material costs, this study proposes the use of biochemical sludge as a raw material. Coupled with iron salt activation and mechanical ball milling technology, a low-cost, high-performance iron-doped mesoporous nano-sludge biochar material is prepared. This material was employed as a particle electrode to construct a three-dimensional electro-Fenton system for the degradation of organic wastewater from sauce-flavor liquor brewing. The results demonstrate that the sludge-based biochar produced through this approach possesses a mesoporous structure, with an average particle size of 187 nm, a specific surface area of 386.28 m<sup>2</sup>/g, and an average pore size of 4.635 nm. Iron is present in the material as multivalent iron ions, which provide more electrochemical reaction sites. Utilizing response surface methodology, the optimized treatment process achieves a maximum COD degradation rate of 71.12%. Compared to the control sample, the average particle size decreases from 287 μm to 187 nm, the specific surface area increases from 44.89 m<sup>2</sup>/g to 386.28 m<sup>2</sup>/g, and the COD degradation rate improves by 61.1%. Preliminary investigations suggest that the iron valence cycle (Fe<sup>2+</sup>/Fe<sup>3+</sup>) and the mass transfer enhancement effect of the mesoporous nano-structure are keys to efficient degradation. The Fe-O-Si structure enhances material stability, with a degradation capacity retention rate of 88.74% after 30 cycles of use. When used as a particle electrode to construct a three-dimensional electro-Fenton system, this material demonstrates highly efficiency in organic matter degradation and shows promising potential for application in the treatment of organic wastewater from sauce-flavor liquor brewing.","dates":{"release":"2025-01-01T00:00:00Z","publication":"2025 Oct","modification":"2026-05-09T03:15:25.363Z","creation":"2026-05-09T03:08:23.422Z"},"accession":"S-EPMC12526432","cross_references":{"pubmed":["41090874"],"doi":["10.3390/nano15191530"]}}