Fotodegradacija tiofanat-metila pod dejstvom svetlosti koja imitira sunčevo zračenje korišćenjem novih kompozitnih fotokatalizatora Naučni rad

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Objavljeno: 2024-01-25
Ažurirano: 2024-01-25
DOI: https://doi.org/10.2298/HEMIND230523004J
Ključne reči:
fotokataliza, titanijum (IV) oksid, unapređeni oksidacioni procesi, zagađenje pesticidima, otpadne vode

Glavni sadržaj članka

Aleksandar Jovanović
Institut za tehnologiju nuklearnih i drugih mineralnih sirovina, Beograd, Srbija
https://orcid.org/0000-0001-9867-9282
Mladen D. Bugarčić
Institut za tehnologiju nuklearnih i drugih mineralnih sirovina, Beograd, Srbija
https://orcid.org/0000-0002-6119-4414
Miroslav D. Sokić1
Institut za tehnologiju nuklearnih i drugih mineralnih sirovina, Beograd, Srbija
https://orcid.org/0000-0002-4468-9503
Tanja S. Barudžija
Univerzitet u Beogradu, Institut za nuklearne nauke "Vinča" - Institut od nacionalnog značaja
https://orcid.org/0000-0002-9240-9609
Vladimir P. Pavićević
Univerzitet u Beogradu, Tehnološko-metalurški fakultet, Beograd, Srbija
https://orcid.org/0000-0003-2180-0085
Aleksandar Marinković
Univerzitet u Beogradu, Tehnološko-metalurški fakultet, Beograd, Srbija
https://orcid.org/0000-0003-3239-5476

Apstrakt

Ovaj rad ima za cilj da prikaže uticaj prisustva nanočestica na površini titanijum (IV) oksida na fotokatalitički kapacitet razlaganja prisutnog organskog polutanta pod dejstvom simulirane sunčeve svetlosti. U tu svrhu, površina rutil titanijum (IV) oksida (r-TiO2) dekorisana je železo vanadatom (FeVO4/r-TiO2) i vanadijumom supstituisanim getitom (Fe1-xVxOOH/r-TiO2). Dobijeni kompoziti su okarakterisani primenom skenirajuće elektronske mikroskopije u emisionom polju uz energetsku disperzionu spektroskopiju, difrakcije X-zraka na sprašenim uzorcima, adsorpcijom azota na tački ključanja primenom Brunauer-Emet-Teler metodologije, infracrvene spektroskopije sa Furijeovom transformacijom u modu smanjene totalne refleksije i spektroskopije difuzne refleksije ultraljubičasto-vidljivog zračenja. Oba fotokatalizatora su pokazala veću fotoaktivnost od komercijalnog r-TiO2 za degradaciju tiofanat-metila (2,5 h umesto 5 h). Tokom ispitivanja ispitivani su faktori kao što su vreme zračenja, količina katalizatora i koncentracija pesticida. Takođe, fotokatalizatori su primenjeni u uza­stopnim višecikličnim testovima degradacije da bi se ispitala njihova efikasnost tokom dužeg vremena eksploatacije. Praćenje brzine uklanjanja vršeno je pomoću  spektrometrije ultralju­bičas­tog/vidljivog zračenja i tečne hromatografije visokih performansi. Pomoćni alat za proveru potpunosti razgradnje fungicida jeste određivanje hemijske potrošnje kiseonika nakon svake faze tretmana. Koncentracija posmatrane zagađujuće materije u tretiranim uzorcima je ispod propisanog zakonskog nivoa. Priprem­ljeni materijali su pokazali veliku stabilnost, postojanost i fotokatalitičku aktivnost što predstavlja dobru osnovu za primenu ovog procesa u realnim postrojenjima za prečišćavanje otpadnih voda.

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Broj časopisa

God. 78 Br. 3 (2024)

Rubrika

Višefazni sistemi u hemijskom inženjerstvu
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Ovaj rad je pod Creative Commons Aуторство-Nekomercijalno-Bez prerade 4.0 Internacionalna licenca.

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Kako citirati

[1]
A. Jovanović, M. . Bugarčić, M. Sokić, T. Barudžija, V. Pavićević, and A. . Marinković, “Fotodegradacija tiofanat-metila pod dejstvom svetlosti koja imitira sunčevo zračenje korišćenjem novih kompozitnih fotokatalizatora: Naučni rad”, Hem Ind, vol. 78, no. 3, pp. 227–240, Jan. 2024, doi: 10.2298/HEMIND230523004J.
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