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Deaktivacija polprevodniških fotokatalizatorjev na osnovi ZnO med razgradnjo izbranih farmacevtikov
ID Ravbar, Miha (Avtor), ID Šuligoj, Andraž (Mentor) Več o mentorju... Povezava se odpre v novem oknu

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Izvleček
Prisotnost organskih onesnažil v okolju je v zadnjih desetletjih vse bolj pereč problem. Fotokataliza kot del naprednih oksidacijskih procesov predstavlja privlačno alternativo obstoječim tehnikam čiščenja. V tem doktorskem delu smo raziskovali sintezo in uporabo cinkovega oksida kot fotokatalizatorja za razgradnjo organskih onesnaževal. Pripravili smo nanodelce cinkovega oksida s pomočjo etanolnega ekstrakta japonskega dresnika. Pri sintezi z rastlinskim ekstraktom smo opazili prednost pri nadzorovanju končne velikosti nanodelcev v primerjavi s klasično solvotermalno sintezo. Čisti cinkov oksid smo nato oplastili z nikljevimi okso-klastri s pomočjo mikrovalovne sinteze, kar je vodilo do izboljšanja nekaterih lastnostih fotokatalizatorja. Preizkusili smo tudi vpliv oplaščevanja na stabilnost in dolgoživost katalizatorja in opazili majhno prednost v primerjavi s cinkovim oksidom pripravljenim po uveljavljenem postopku. Stabilnost cinkovega oksida pri razgradnji farmacevtikov smo podrobneje preučili z izvedbo do 15 zaporednih razgradenj farmacevtika z istim, večkrat uporabljenim fotokatalizatorjem. Poleg modelnega poskusa smo izvedli še dodatnih nekaj poskusov, pri katerih smo spreminjali posamezne faktorje (dodatek vodikovega peroksida, dodatek huminske kisline, zamenjava farmacevtika, zamenjava katalizatorja z oplaščenim), da bi preučili njihov vpliv na potek deaktivacije katalizatorja. Izvedli smo poskus z dodatkom oksidanta pri razgradnji, z dodatkom huminske kisline kot predstavnika naravno prisotnih organskih spojin v odpadnih vodah, z zamenjavo farmacevtika ter z zamenjavo katalizatorja s cinkovim oksidom, oplaščenim z nikljevimi okso-klastri. Na koncu vseh poskusov smo uporabljeni fotokatalizator okarakterizirali z različnimi analitskimi tehnikami (XRD, XPS, FTIR, TGA, BET) in poskusili določiti stopnjo deaktivacije katalizatorja ter vzrok za to. Primerjali smo tudi vpliv faktorjev na zastrupljanje oziroma deaktivacijo katalizatorjev. Poleg uporabe fotokatalizatorja v šaržnem reaktorju, smo ga tudi imobilizirali na steklene kroglice, s katerimi smo vzpostavili pretočni reaktor. Le tega smo uporabili v bolj dolgotrajnem poskusu, kjer smo preverili dolgoročno stabilnost fotokatalizatorja (≈300 h), tako da smo spremljali stopnjo razgradnje antibiotika pri pretoku skozi reaktor. Pri tem smo preverili tudi vpliv hitrosti pretoka na stabilnost oziroma pojav deaktivacije katalizatorja.

Jezik:Slovenski jezik
Ključne besede:-
Vrsta gradiva:Doktorsko delo/naloga
Tipologija:2.08 - Doktorska disertacija
Organizacija:FKKT - Fakulteta za kemijo in kemijsko tehnologijo
Leto izida:2025
PID:20.500.12556/RUL-170149 Povezava se odpre v novem oknu
COBISS.SI-ID:243843587 Povezava se odpre v novem oknu
Datum objave v RUL:02.07.2025
Število ogledov:312
Število prenosov:61
Metapodatki:XML DC-XML DC-RDF
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Sekundarni jezik

Jezik:Angleški jezik
Naslov:Deactivation of ZnO-based semiconductor photocatalysts during the degradation of selected pharmaceuticals
Izvleček:
The presence of organic pollutants in the environment has been a growing problem in recent decades. As part of advanced oxidation processes, photocatalysis represents an attractive alternative to existing treatment techniques. In this thesis we investigated the synthesis and use of zinc oxide as a photocatalyst for the degradation of organic pollutants. Zinc oxide nanoparticles were prepared using an ethanolic extract of Japanese knotweed. We observed that the synthesis with the plant extract allowed for a finer control over the final nanoparticle size compared to the classical solvothermal synthesis. Pure zinc oxide was also decorated with nickel-oxo clusters, using microwave-assisted synthesis, leading to an improvement in some of the photocatalysts properties. We also tested the effect of the decoration on the stability and longevity of the catalyst and noticed a small advantage compared to zinc oxide prepared by the established process. The stability of zinc oxide during degradation of pharmaceuticals was also investigated in more detail by carrying out up to 15 consecutive degradations of the pharmaceutical with the same photocatalyst used several times. In addition to the model experiment, a few more experiments were carried out in which individual factors were varied (addition of hydrogen peroxide, addition of humic acid, swap of the pharmaceutical and swap of the catalyst with the decorated one) in order to investigate their influence on the catalyst deactivation process. We carried out an experiment with the addition of an oxidant during degradation, with the addition of humic acid as a representative of naturally occurring organic compounds in effluents, with a different pharmaceutical and with the replacement of the catalyst by zinc oxide decorated with nickel-oxo clusters. At the end of the degradations, the photocatalyst used was characterised by different analytical techniques (XRD, XPS, FTIR, TGA, BET) and an attempt was made to determine the degree of deactivation of the catalyst and its cause. The influence of factors on catalyst poisoning or deactivation was also compared. In addition to using the photocatalyst in a batch reactor, it was also immobilized on glass beads to create a flow-through reactor. The flow-through reactor was used in a more long-term experiment where the long-term stability of the photocatalyst (≈300 h) was investigated by monitoring the degradation rate of the antibiotic as it flowed through the reactor. The effect of the flow rate on the stability or deactivation of the catalyst was also verified.

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