Coagulation studies on photodegraded and photocatalytically degraded polystyrene microplastics using polyaluminium chloride

•Photo and photocatalytic degradation of PS under UV-C, UV-A and solar irradiation.•Photodegradation using UV light is effective in removal of polystyrene microplastic.•Oxygen to carbon ratio of polystyrene microplastics increased after UV irradiation.•Large sized MPs (300–150 μm) showed better remo...

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Published in:Waste management (Elmsford) 2023-10, Vol.170, p.329-340
Main Authors: Meera, G., Sasidharan Pillai, Indu M., Reji, P.G., Sajithkumar, K.J., Priya, K.L., Chellappan, Suchith
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Language:English
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Coagulation
Microplastics
Photoaging
Removal efficiency
Ultraviolet irradiation
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container_title Waste management (Elmsford)
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Sasidharan Pillai, Indu M.
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description •Photo and photocatalytic degradation of PS under UV-C, UV-A and solar irradiation.•Photodegradation using UV light is effective in removal of polystyrene microplastic.•Oxygen to carbon ratio of polystyrene microplastics increased after UV irradiation.•Large sized MPs (300–150 μm) showed better removal efficiency under UV-C irradiation.•Tentative degradation pathway of photodegraded PS microplastic by FTIR analysis. Microplastics are ubiquitous persistent emerging contaminants, and its presence has been detected even in the most pristine and fragile ecosystems. Advanced oxidation processes are one of the novel degradation technologies used for the elimination of microplastics from the environment. In this study, the effect of ultraviolet C (UV-C, 253.7 nm) and ultraviolet A (UV-A, 365 nm) irradiations on polystyrene (PS) microplastic properties in the presence and absence of titanium dioxide were studied along with their coagulation performances using polyaluminium chloride (PAC). The effects of solar irradiation on the chemical properties of microplastics in aqueous and dry conditions were also investigated. PS microplastics (1.5 g) in three size ranges, 300–150 μm, 150–75 μm, and
doi_str_mv 10.1016/j.wasman.2023.09.018
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Microplastics are ubiquitous persistent emerging contaminants, and its presence has been detected even in the most pristine and fragile ecosystems. Advanced oxidation processes are one of the novel degradation technologies used for the elimination of microplastics from the environment. In this study, the effect of ultraviolet C (UV-C, 253.7 nm) and ultraviolet A (UV-A, 365 nm) irradiations on polystyrene (PS) microplastic properties in the presence and absence of titanium dioxide were studied along with their coagulation performances using polyaluminium chloride (PAC). The effects of solar irradiation on the chemical properties of microplastics in aqueous and dry conditions were also investigated. PS microplastics (1.5 g) in three size ranges, 300–150 μm, 150–75 μm, and &lt;75 μm were used during this experiment. After 45 days of irradiation, samples showed discolouration, brittleness, and loss of hydrophobicity. Images obtained from scanning electron microscope revealed smoothening and melting of PS surfaces upon UV exposure. Attenuated total reflectance- Fourier transform infrared spectroscopy and X-ray photon spectroscopy of photoaged samples revealed chemical alterations, bond cleavage and formation of oxygenated functional groups on microplastic surfaces. PAC coagulation of samples before and after UV irradiation showed drastic differences in removal efficiencies, with UV-C irradiated microplastics exhibiting maximum efficiency. Large sized and photocatalytically degraded microplastics showed better removal efficiencies than small sized particles. 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Images obtained from scanning electron microscope revealed smoothening and melting of PS surfaces upon UV exposure. Attenuated total reflectance- Fourier transform infrared spectroscopy and X-ray photon spectroscopy of photoaged samples revealed chemical alterations, bond cleavage and formation of oxygenated functional groups on microplastic surfaces. PAC coagulation of samples before and after UV irradiation showed drastic differences in removal efficiencies, with UV-C irradiated microplastics exhibiting maximum efficiency. Large sized and photocatalytically degraded microplastics showed better removal efficiencies than small sized particles. 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subjects Coagulation
Microplastics
Photoaging
Removal efficiency
Ultraviolet irradiation
title Coagulation studies on photodegraded and photocatalytically degraded polystyrene microplastics using polyaluminium chloride
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