Immobilized TiO<sub>2</sub> on glass spheres applied to heterogeneous photocatalysis: photoactivity, leaching and regeneration process

Cunha, Deivisson Lopes; Kuznetsov, Alexei; Achete, Carlos A.; Machado, Antônio Eduardo da Hora; Marques, Márcia

doi:10.7717/peerj.4464

Cited by 93 publications

(50 citation statements)

References 61 publications

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“…In fact, the MB relative concentration gradually decreased in the run time and almost complete decolorization was achieved after 120 min of visible light irradiation. Several published papers have reported the removal of MB with fixed bed photoreactors irradiated by artificial light sources, as well as with solar photocatalytic reactors using structured photocatalysts (Table 1) [34][35][36][37][38]. For example, almost total MB decolorization was achieved after 48 h in the solar photoreactor proposed by Sutisna et al [34], in which TiO 2 nanoparticles were placed as coating on transparent granules and used in the prototype of a flat-panel photoreactor.…”

Section: Discoloration and Mineralization Of Methylene Blue With The mentioning

confidence: 99%

“…El-Mekkawi et al [35] observed the complete decolorization after 5 h under the sunlight irradiation using a solar concentrator photoreactor prototype with TiO 2 deposited on polyethylene terephthalate (PET) textile substrate sheets. In some cases, it was reported that MB degraded more than 96% in up to 90 min of reaction using TiO 2 immobilized on glass spheres [36]. However, the same authors used a lab scale compound parabolic collector reactor irradiated by lamp at high electrical power (300 W) simulating the solar spectrum.…”

Section: Discoloration and Mineralization Of Methylene Blue With The mentioning

confidence: 99%

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Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

2019

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A packed bed photoreactor was developed using a structured photocatalyst active under visible light. The packed bed reactor was irradiated by visible light-emitting diodes (LEDs) for the evaluation of photocatalytic activity in the removal of different types of water pollutants. By using a flexible LEDs strip as the external light source, it was possible to use a simple cylindrical geometry for the photoreactor, thereby enhancing the contact between the photocatalyst and the water to be treated. The visible light active structured photocatalyst was composed by N-doped TiO 2 particles supported on polystyrene spheres. Photocatalytic results showed that the almost total methylene blue decolorization was achieved after 120 min of irradiation. Moreover, the developed packed bed photoreactor was effective in the removal of ceftriaxone, paracetamol, and caffeine, allowing it to reach the almost total degradation of the pollutants and a total organic carbon removal above 80% after 180 min of visible light irradiation. of pollutants through the application of conventional lamps as light sources [20]. However, since conventional lamps are expensive in terms of manufacturing, as well as electricity consumption, many studies have been devoted to photocatalytic reactors that exploit the solar spectrum [21].But it is necessary to take into account the many limitations related to solar photoreactors. For example, in a solar compound parabolic collector (CPC), despite the fact that the reactor is formed by small tubes, the area equipped by the parabolic collector for light harvesting is huge. So, the installation of these systems also requires a large area [22] to avoid that the single modules projecting shadows upon each other [23]. Another limitation this kind of system is connected to the use of only direct sunlight [24,25]. Thus, the solar photoreactors do not work efficiently during cloudy days and night time. The recent rapid advances in light-emitting diodes (LEDs) technology have made possible a new frontier for a wide range of lighting applications, including photocatalysis and, consequently, photoreactor design [26,27]. In fact, the energy conversion efficiency of LEDs has increased exponentially in recent years, making them a suitable light source for the design of compact photocatalytic reactors for water and wastewater treatment [28,29], as well as for the removal of hazardous compounds from gaseous streams [30], overcoming the limitations related to the developing of photocatalytic reactors into pilot scale level. With the use of LEDs, the design of photoreactors could be significantly facilitated and, by using a flexible LEDs strip as the external light source, it is possible to use simple cylindrical geometry for photoreactor, thereby enhancing the contact between the photocatalyst and the water to be treated.Moreover, cylindrical geometry for photocatalytic reactors is the most used in solar through collectors [31], and it is the simplest configuration, allowing a possible scale-up of photocatalytic systems for...

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Section: Discoloration and Mineralization Of Methylene Blue With The mentioning

confidence: 99%

Section: Discoloration and Mineralization Of Methylene Blue With The mentioning

confidence: 99%

Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

2019

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“…Similarly, some important processes such as waste water remediation, biofuel synthesis, and catalytic wet air oxidation reaction have also been marred by leaching of the active species. There are a few other commercially important reactions as well where leaching has been detected …”

Section: Introductionmentioning

confidence: 99%

Bi₂O₃@mSiO₂ as an Environmentally Benign and Sustainable Solid Acid Catalyst for Benzoylation of Aromatics: Impact of Silica Encapsulation on Catalyst Leaching and Reaction Synergy

Jain

Samant

2020

ChemistrySelect

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Leaching of active species is one of the major causes of catalyst deactivation. The accumulation of this leached species as chemical waste can be detrimental to the environment. In this study, a series of environmentally benign core-shell catalysts of type Bi 2 O 3 @mSiO 2 were synthesized to address these issues. The catalysts, varying in silica content and shell thickness, were characterized and evaluated for Friedel-Crafts benzoylation. Amongst them, Bi-4 (containing 71.8 % Bi 2 O 3 ), having shell thickness of ∼ 42 nm, showed the best response under optimized conditions. Textural analysis of Bi-4 confirmed the mesoporous nature of shell, with average pore diameter of ∼ 40 Å and surface area of 62 m 2 /g. During the reaction, the Bi 2 O 3 core was converted to BiOCl, which was easily recycled back to its original form. No leaching or any loss in catalytic activity was observed for the recycled catalyst during reuse. Thus, an inexpensive, reusable and environmentally benign catalyst is proposed.

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“…Amongst various fabrications and application methods, positioning a photocatalyst near the surface of water, and on a floating support have been investigated by several researchers as it allows higher oxygenation and illumination [17,[32][33][34][35][36]. Although the initial floating supported photocatalysts were shown to be effective to clean oil slicks on water [17], the ingestion risk by fishes and animals in water and uncertain toxicity of the degradation intermediates limited their development.…”

Section: Introductionmentioning

confidence: 99%

Comparative Study of Four TiO2-Based Photocatalysts to Degrade 2,4-D in a Semi-Passive System

Heydari

Hollman

Achari

et al. 2019

Water

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In this study, the relative efficiency of four forms of supported titanium dioxide (TiO2) as a photocatalyst to degrade 2,4-dichlorophenoxyacetic acid (2,4-D) in Killex®, a commercially available herbicide was studied. Coated glass spheres, anodized plate, anodized mesh, and electro-photocatalysis using the anodized mesh were evaluated under an ultraviolet – light-emitting diode (UV-LED) light source at λ = 365 nm in a semi-passive mode. Energy consumption of the system was used to compare the efficiency of the photocatalysts. The results showed both photospheres and mesh consumed approximately 80 J/cm3 energy followed by electro-photocatalysis (112.2 J/cm3), and the anodized plate (114.5 J/cm3). Although electro-photocatalysis showed the fastest degradation rate (K = 5.04 mg L−1 h−1), its energy consumption was at the same level as the anodized plate with a lower degradation rate constant of 3.07 mg L−1 h−1. The results demonstrated that three-dimensional nanotubes of TiO2 surrounding the mesh provide superior degradation compared to one-dimensional arrays on the planar surface of the anodized plate. With limited broad-scale comparative studies between varieties of different TiO2 supports, this study provides a comparative analysis of relative degradation efficiencies between the four photocatalytic configurations.

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Immobilized TiO₂ on glass spheres applied to heterogeneous photocatalysis: photoactivity, leaching and regeneration process

Cited by 93 publications

References 61 publications

Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

Bi₂O₃@mSiO₂ as an Environmentally Benign and Sustainable Solid Acid Catalyst for Benzoylation of Aromatics: Impact of Silica Encapsulation on Catalyst Leaching and Reaction Synergy

Comparative Study of Four TiO2-Based Photocatalysts to Degrade 2,4-D in a Semi-Passive System

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Immobilized TiO2 on glass spheres applied to heterogeneous photocatalysis: photoactivity, leaching and regeneration process

Cited by 93 publications

References 61 publications

Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

Packed Bed Photoreactor for the Removal of Water Pollutants Using Visible Light Emitting Diodes

Bi2O3@mSiO2 as an Environmentally Benign and Sustainable Solid Acid Catalyst for Benzoylation of Aromatics: Impact of Silica Encapsulation on Catalyst Leaching and Reaction Synergy

Comparative Study of Four TiO2-Based Photocatalysts to Degrade 2,4-D in a Semi-Passive System

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Product

Resources

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Immobilized TiO₂ on glass spheres applied to heterogeneous photocatalysis: photoactivity, leaching and regeneration process

Bi₂O₃@mSiO₂ as an Environmentally Benign and Sustainable Solid Acid Catalyst for Benzoylation of Aromatics: Impact of Silica Encapsulation on Catalyst Leaching and Reaction Synergy