Advanced Technology in Environmental Remediation and Resource Utilization

© 2022 by the authors; CC BY-NC-ND license

peracetic acid; ferrous ions; electrolysis; synergistic effect; dye elimination; seawater splitting; catalyst; oxygen evolution reaction; hydrogen evolution reaction; hypochlorite evolution reaction; anti-corrosion; UV irradiation; sodium perborate; activation; humic acid removal; decomposition mechanism; electrostatic anti-fouling; calcium carbonate; ferrous ion; corrosion; molecular dynamics; electrostatic field; supercapacitor; graphene; graphene composite; application; activated carbon; spent radioactive resin; cement solidification; sulfoaluminate cement; metakaolin; nuclides leaching; mixture design; heterotrophic nitrification; aerobic denitrification; low-temperature resistance; salt tolerance; Vibrio sp. LY1024; mariculture wastewater treatment; blast furnace dust; wet electrostatic precipitator; chemical coagulant; synergy; dust removal; electrowinning; recycling; electrical and electronic waste; leaching; tin; noble metals; selenium nanoparticles; lignosulfonate; starch sodium octenyl succinate; biopolymer; organic dye; date palm biomass; carbon microspheres; phosphoric acid activation; methylene blue; adsorption; magnesium phosphate cement (MPC); X-ray diffraction; water purification; fluoride adsorption; isotherms; scanning electron microscopy