Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe

Microbial pathogenic contaminants such as bacteria, viruses and protozoa pose a major threat to environment human health that can cause deadly infectious diseases. One promising way of disinfection activity is by photocatalysis. Bismuth ferrite (BFO) has been regarded as an efficient visible-light d...

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Main Author: Daub, Nur Atiqah
Format: Thesis
Language:English
Published: 2022
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Online Access:http://eprints.utm.my/id/eprint/101588/1/NurAtiqahDaubMSChE2022.pdf
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spelling my.utm.1015882023-06-26T06:49:34Z http://eprints.utm.my/id/eprint/101588/ Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe Daub, Nur Atiqah TP Chemical technology Microbial pathogenic contaminants such as bacteria, viruses and protozoa pose a major threat to environment human health that can cause deadly infectious diseases. One promising way of disinfection activity is by photocatalysis. Bismuth ferrite (BFO) has been regarded as an efficient visible-light driven material for photocatalyst due to its narrow band gap value. However, rapid recombination of photogenerated electron (e-) – hole (h+) pairs has limits its application as photocatalyst. To overcome this, BFO-activated carbon nanocomposites (BFO-AC) was synthesized by ultrasonication method with various ratio of activated carbon. Characterization using X-Ray diffraction analysis showed no change in crystallinity of BFO nanoparticles when activated carbon was incorporated into nanoparticles. By using the UV-Vis diffuse reflactance spectroscopy (UVDRS), the emission band of all BFO and BFO-AC nanocomposites were found within visible light range (400-700 nm) and BA (1:1.5) was having the lowest band gap value of 1.86 eV. Interestingly, after the addition of AC, the Brunauer–Emmett–Teller (BET) surface area of BA (1:0.5), BA (1:1) and BA (1:1.5) dramatically increased ie., 267.51 m2/g, 351.82 m2/g and 862.99 m2/g, respectively. BET results indicate BA (1:1.5) has the highest surface area due to its porous property. The field emission scanning electron micrograph has shown that BA (1:1.5) possess a better distribution and less agglomeration. The photoluminescence analysis demonstrated the intensity of all BFO-AC nanocomposites decreases compared to pristine BFO. The decrease of photoluminescence indicate the lower rate of electron (e-) – hole (h+) pairs recombination. Photocatalytic disinfection of S.aureus by AC, BFO, BA (1:0.5) and BA (1:1) were obtained within 150 min, 120 min, 120 min and 90 min, respectively. BA (1:1.5) exhibited the strongest bactericidal activity as a complete inactivation of S.aureus was achieved within 60 min. The surface and morphology of S.aureus were characterized by transmission electron microscopy analysis. Bacterial cell had a smooth and spherical shape before being irradiated under visible light. However, the bacterial cell were severely damaged and ruptured as the irradiation time increased, implying that S.aureus was killed. It is herein worth noting that the incorporation of AC onto BFO significantly improved the performance of photocatalytic disinfection of S.aureus under visible-light irradiation. 2022 Thesis NonPeerReviewed application/pdf en http://eprints.utm.my/id/eprint/101588/1/NurAtiqahDaubMSChE2022.pdf Daub, Nur Atiqah (2022) Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe. Masters thesis, Universiti Teknologi Malaysia. http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:150720
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
language English
topic TP Chemical technology
spellingShingle TP Chemical technology
Daub, Nur Atiqah
Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
description Microbial pathogenic contaminants such as bacteria, viruses and protozoa pose a major threat to environment human health that can cause deadly infectious diseases. One promising way of disinfection activity is by photocatalysis. Bismuth ferrite (BFO) has been regarded as an efficient visible-light driven material for photocatalyst due to its narrow band gap value. However, rapid recombination of photogenerated electron (e-) – hole (h+) pairs has limits its application as photocatalyst. To overcome this, BFO-activated carbon nanocomposites (BFO-AC) was synthesized by ultrasonication method with various ratio of activated carbon. Characterization using X-Ray diffraction analysis showed no change in crystallinity of BFO nanoparticles when activated carbon was incorporated into nanoparticles. By using the UV-Vis diffuse reflactance spectroscopy (UVDRS), the emission band of all BFO and BFO-AC nanocomposites were found within visible light range (400-700 nm) and BA (1:1.5) was having the lowest band gap value of 1.86 eV. Interestingly, after the addition of AC, the Brunauer–Emmett–Teller (BET) surface area of BA (1:0.5), BA (1:1) and BA (1:1.5) dramatically increased ie., 267.51 m2/g, 351.82 m2/g and 862.99 m2/g, respectively. BET results indicate BA (1:1.5) has the highest surface area due to its porous property. The field emission scanning electron micrograph has shown that BA (1:1.5) possess a better distribution and less agglomeration. The photoluminescence analysis demonstrated the intensity of all BFO-AC nanocomposites decreases compared to pristine BFO. The decrease of photoluminescence indicate the lower rate of electron (e-) – hole (h+) pairs recombination. Photocatalytic disinfection of S.aureus by AC, BFO, BA (1:0.5) and BA (1:1) were obtained within 150 min, 120 min, 120 min and 90 min, respectively. BA (1:1.5) exhibited the strongest bactericidal activity as a complete inactivation of S.aureus was achieved within 60 min. The surface and morphology of S.aureus were characterized by transmission electron microscopy analysis. Bacterial cell had a smooth and spherical shape before being irradiated under visible light. However, the bacterial cell were severely damaged and ruptured as the irradiation time increased, implying that S.aureus was killed. It is herein worth noting that the incorporation of AC onto BFO significantly improved the performance of photocatalytic disinfection of S.aureus under visible-light irradiation.
format Thesis
author Daub, Nur Atiqah
author_facet Daub, Nur Atiqah
author_sort Daub, Nur Atiqah
title Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
title_short Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
title_full Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
title_fullStr Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
title_full_unstemmed Nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
title_sort nanocomposite of bismuth ferrite and activated carbon for photocatalytic disinfection of microbe
publishDate 2022
url http://eprints.utm.my/id/eprint/101588/1/NurAtiqahDaubMSChE2022.pdf
http://eprints.utm.my/id/eprint/101588/
http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:150720
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