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dc.contributor.authorAVİYENTE, VİKTORYA
dc.contributor.authorÖZÖN, ECE
dc.contributor.authorArslan, Evrim
dc.contributor.authorSavun-Hekimoglu, Basak
dc.contributor.authorERDİNÇLER, AYŞEN
dc.contributor.authorZiylan-Yavas, Asu
dc.contributor.authorInce, Nilsun H.
dc.date.accessioned2021-12-10T13:02:39Z
dc.date.available2021-12-10T13:02:39Z
dc.identifier.citationZiylan-Yavas A., Ince N. H. , ÖZÖN E., Arslan E., AVİYENTE V., Savun-Hekimoglu B., ERDİNÇLER A., "Oxidative decomposition and mineralization of caffeine by advanced oxidation processes: The effect of hybridization", ULTRASONICS SONOCHEMISTRY, cilt.76, 2021
dc.identifier.issn1350-4177
dc.identifier.othervv_1032021
dc.identifier.otherav_ea263251-eaee-49b2-a412-ba328ecac2c9
dc.identifier.urihttp://hdl.handle.net/20.500.12627/175274
dc.identifier.urihttps://doi.org/10.1016/j.ultsonch.2021.105635
dc.description.abstractThe study consists of a detailed investigation of the degradability of the emerging water contaminant-caffeine by homogeneous and heterogeneous Advanced Oxidation Processes (AOP's), estimation of a synergy index for each hybrid operation thereof, and proposing the most plausible reaction mechanisms that are consistent with the experimental data. It also encompasses evaluation of the effect of the water matrix represented by carbonate species and humic acids, as strong scavengers of hydroxyl radicals. The results showed that single AOP's such as sonolysis (577 kHz) and photolysis with H2O2 provided complete caffeine elimination, but they were insufficient for the mineralization of the compound. Hybrid AOP's were considerably more effective, particularly when operated at a heterogeneous mode using commercial TiO2. The most effective hybrid process was UV-H2O2/TiO2, which provided more than 75% TOC decay at the minimum test doses of the reagent and catalyst. While the addition of ultrasound to the process significantly increased the rate of caffeine decomposition, it reduced the overall degradation of the compound to 64% in terms of TOC decay. The antagonistic effect was attributed to the formation of excess H2O2, and the presence of cavity clouds and/or high density layers that inhibited the transmission of UV light. The effect of natural water ingredients was found to reduce the reaction rates, signifying the major contribution of hydroxyl radicals to the destruction of caffeine. The proposed reaction mechanisms based on OH radical attack and the calculated energy barriers were in good agreement with the experimentally detected reaction byproducts.
dc.language.isoeng
dc.subjectBiyokimya
dc.subjectAlkoloidler
dc.subjectTemel Bilimler
dc.subjectChemistry (miscellaneous)
dc.subjectGeneral Chemistry
dc.subjectAcoustics and Ultrasonics
dc.subjectPhysical Sciences
dc.subjectElektromanyetizma, Akustik, Isı Transferi, Klasik Mekanik ve Akışkanlar Dinamiği
dc.subjectAkustik
dc.subjectKimya
dc.subjectKİMYA, MULTİDİSİPLİNER
dc.subjectTemel Bilimler (SCI)
dc.subjectFizik
dc.subjectAKUSTİK
dc.titleOxidative decomposition and mineralization of caffeine by advanced oxidation processes: The effect of hybridization
dc.typeMakale
dc.relation.journalULTRASONICS SONOCHEMISTRY
dc.contributor.departmentBoğaziçi Üniversitesi , ,
dc.identifier.volume76
dc.contributor.firstauthorID2703407


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