EER :: Environmental Engineering Research

Treatment of Pharmaceutical Wastewaters by Hydrogen Peroxide and Zerovalent Iron

Byeong-Cheol Jeon, Se-Yong Nam, Young-Kwon Kim

Environmental Engineering Research. 2014;19(1):9-14. Published online 2014 Mar 10 DOI: https://doi.org/10.4491/eer.2014.19.1.009

Citations to this article as recorded by

Experimental treatment of pickled vegetable wastewater by electrofenton method based on modified PbO2 electrode

Likun Huang, Jingyi Zhang, Guangzhi Wang, Dandan Wang, Zhe Li, Simin Zhou, Xinyi Di, Xinyu Feng

Process Safety and Environmental Protection.2025; 193: 514. CrossRef

Application of electro-Fenton technology for the degradation of imidacloprid from pesticide wastewater

Jia-Zih Wang, Thi-Hanh Ha, Chart Chiemchaisri, Ming-Chun Lu

Journal of Water Process Engineering.2024; 63: 105504. CrossRef

Application of Micron-Sized Zero-Valent Iron (ZVI) for Decomposition of Industrial Amaranth Dyes

Dominika Ścieżyńska, Dominika Bury, Michał Jakubczak, Jan Bogacki, Agnieszka Jastrzębska, Piotr Marcinowski

Materials.2023; 16(4): 1523. CrossRef

Toward rapid reduction of carbon tetrachloride in water by zero-valent aluminum/persulfate system

Hanchen Wang, Yichao Xue, Shiying Yang, Yang Li, Qianfeng Li

Chemosphere.2022; 303: 135132. CrossRef

Zero-valent iron driven bioconversion of glycerol to 1,3-propanediol using Klebsiella pneumoniae L17

Da Seul Kong, Changman Kim, Young Eun Song, Jiyun Baek, Hyeon Sung Im, Jung Rae Kim

Process Biochemistry.2021; 106: 158. CrossRef

H2O2 self-providing synergistic chemodynamic/photothermal therapy using graphene oxide supported zero valence iron nanoparticles

Miao Xu, Qin Li, Yi Xiang, Shanshan Yuan, Yihan Wu, Jing Zhang, Jinliang Liu, Xiaohui Zhu, Yong Zhang

RSC Advances.2021; 11(46): 28973. CrossRef

Removal of triclosan in a Fenton-like system mediated by graphene oxide: Reaction kinetics and ecotoxicity evaluation

Jianbiao Peng, Yaozong Zhang, Chaonan Zhang, Dong Miao, Jianhua Li, Haijin Liu, Lianhong Wang, Shixiang Gao

Science of The Total Environment.2019; 673: 726. CrossRef

A comparative study on applicability of nano-sized iron(II, III) oxide in ultrasonicated Fenton process

Serkan Sahınkaya, Sennur Merve Yakut

Environmental Engineering Research.2019; 25(1): 36. CrossRef

Manganese oxide nanorods as a robust Fenton-like catalyst at neutral pH: Crystal phase-dependent behavior

Eun-Ju Kim, Dasom Oh, Chung-Seop Lee, Jianyu Gong, Jungwon Kim, Yoon-Seok Chang

Catalysis Today.2017; 282: 71. CrossRef

Catalytic effect of low concentration carboxylated multi-walled carbon nanotubes on the oxidation of disinfectants with Cl-substituted structure by a Fenton-like system

Jianbiao Peng, Jie Xue, Jianhua Li, Zhongkun Du, Zunyao Wang, Shixiang Gao

Chemical Engineering Journal.2017; 321: 325. CrossRef

Degradation of methyl orange by heterogeneous Fenton-like oxidation on a nano-organometallic compound in the presence of multi-walled carbon nanotubes

M. Arshadi, M.K. Abdolmaleki, F. Mousavinia, A. Khalafi-Nezhad, H. Firouzabadi, A. Gil

Chemical Engineering Research and Design.2016; 112: 113. CrossRef

Stabilization of hydrogen peroxide using tartaric acids in Fenton and Fenton-like oxidation

Hyung Suk Oh, Jeong-Jin Kim, Young-Hun Kim

Korean Journal of Chemical Engineering.2016; 33(3): 885. CrossRef

Enhanced production of reactive oxidants by Fenton-like reactions in the presence of carbon materials

Jiwon Seo, Hye-Jin Lee, Hongshin Lee, Hyung-Eun Kim, Jeong-Yong Lee, Han S. Kim, Changha Lee

Chemical Engineering Journal.2015; 273: 502. CrossRef

Polyphosphate-enhanced production of reactive oxidants by nanoparticulate zero-valent iron and ferrous ion in the presence of oxygen: Yield and nature of oxidants

Hak-Hyeon Kim, Hongshin Lee, Hyung-Eun Kim, Jiwon Seo, Seok Won Hong, Jeong-Yong Lee, Changha Lee

Water Research.2015; 86: 66. CrossRef