0000000000077206

AUTHOR

Zhao Wang

showing 2 related works from this author

Ibuprofen degradation using a Co-doped carbon matrix derived from peat as a peroxymonosulphate activator

2021

The wider presence of pharmaceuticals and personal care products in nature is a major cause for concern in society. Among pharmaceuticals, the anti-inflammatory drug ibuprofen has commonly been found in aquatic and soil environments. We produced a Co-doped carbon matrix (Co-P 850) through the carbonization of Co2+ saturated peat and used it as a peroxymonosulphate activator to aid ibuprofen degradation. The properties of Co-P 850 were analysed using field emission scanning electron microscopy, energy filtered transmission electron microscopy and X-ray photoelectron spectroscopy. The characterization results showed that Co/Fe oxides were generated and tightly embedded into the carbon matrix …

advanced oxidation processhapetushajotusBicarbonateIbuprofen010501 environmental sciencespharmaceuticals and personal care productsComputing Methodologies01 natural sciencesBiochemistryChlorideCatalysisCatalysisturveSoil03 medical and health scienceschemistry.chemical_compoundkatalyytit0302 clinical medicineX-ray photoelectron spectroscopyDissolved organic carbonmedicineEnergy filtered transmission electron microscopy030212 general & internal medicineibuprofenjäteveden käsittely0105 earth and related environmental sciencesGeneral Environmental Sciencecarbon-based catalystvedenpuhdistuscobalt oxidesCarbonizationorganic chemicalsAdvanced oxidation processlääkeaineetCarbonPeroxidesibuprofeenichemistryaktiivihiilioksiditQuantum TheoryWater Pollutants ChemicalNuclear chemistrymedicine.drugEnvironmental Research
researchProduct

Heterogeneous fenton oxidation using magnesium ferrite nanoparticles for ibuprofen removal from wastewater: optimization and kinetics studies

2020

In this study, the catalytic properties of Fenton-like catalyst based on magnesium ferrite nanoparticles for IBP degradation were examined. Structural and morphological studies showed the low crystallinity and mesoporous structure for the catalyst obtained via a glycine-nitrate method. The influences of catalyst dosage, oxidant concentration, and solution pH on the pollutant degradation were investigated. The pseudo-first-order model describes kinetic data, and under optimal condition (catalyst dose of 0.5 g L-1, H2O2 concentration of 20.0 mM, and pH of 8.0), apparent rate constant reached 0.091 min-1. It was shown that Fenton reaction was mainly induced by iron atoms on the catalyst surfac…

inorganic chemicalshapetusMaterials scienceArticle SubjectKineticsNanoparticlejätevesi02 engineering and technology010501 environmental sciences01 natural sciencesCatalysisCrystallinitykatalyytitReaction rate constantT1-995General Materials ScienceTechnology (General)jäteveden käsittely0105 earth and related environmental sciencesvedenpuhdistusmagnesium ferrite ; ibuprofen removal ; fenton oxidationlääkeaineet021001 nanoscience & nanotechnologyibuprofeeniWastewaterChemical engineeringnanohiukkasetLeaching (metallurgy)0210 nano-technologyMesoporous material
researchProduct