Hydrogen production and simultaneous photoelectrocatalytic pollutant oxidation using a TiO2/WO3 nanostructured photoanode under visible light irradiation

Guaraldo, Thaís Tasso; Gonçales, Vinícius R.; Silva, Bianca Ferreira da; Torresi, Susana Inês Córdoba de; Zanoni, María Valnice Boldrin

doi:10.1016/j.jelechem.2015.07.034

Cited by 40 publications

(7 citation statements)

References 26 publications

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“…This was attributed to the improvement of the solar spectrum absorption and, additionally, by the enhancement of the photogenerated carrier transport. The coupling of WO 3 with TiO 2 was also applied in Reactive Black 5 degradation in the PEC process [181]. The bicomponent material applied as a photoanode provided faster dye degradation combined with simultaneous improved hydrogen generation in comparison with the unmodified photoelectrode.…”

Section: Composite Semiconductor Photoelectrode Materialsmentioning

confidence: 99%

Semiconductor Electrode Materials Applied in Photoelectrocatalytic Wastewater Treatment—an Overview

Kuśmierek

2020

Catalysts

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Industrial sources of environmental pollution generate huge amounts of industrial wastewater containing various recalcitrant organic and inorganic pollutants that are hazardous to the environment. On the other hand, industrial wastewater can be regarded as a prospective source of fresh water, energy, and valuable raw materials. Conventional sewage treatment systems are often not efficient enough for the complete degradation of pollutants and they are characterized by high energy consumption. Moreover, the chemical energy that is stored in the wastewater is wasted. A solution to these problems is an application of photoelectrocatalytic treatment methods, especially when they are coupled with energy generation. The paper presents a general overview of the semiconductor materials applied as photoelectrodes in the treatment of various pollutants. The fundamentals of photoelectrocatalytic reactions and the mechanism of pollutants treatment as well as parameters affecting the treatment process are presented. Examples of different semiconductor photoelectrodes that are applied in treatment processes are described in order to present the strengths and weaknesses of the photoelectrocatalytic treatment of industrial wastewater. This overview is an addition to the existing knowledge with a particular focus on the main experimental conditions employed in the photoelectrocatalytic degradation of various pollutants with the application of semiconductor photoelectrodes.

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Section: Composite Semiconductor Photoelectrode Materialsmentioning

confidence: 99%

Semiconductor Electrode Materials Applied in Photoelectrocatalytic Wastewater Treatment—an Overview

Kuśmierek

2020

Catalysts

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“…On the contrary, deposition of titania on the top of the WO3 film may result in the passivation of surface defects of the latter, and this would limit charge recombination sites. Passivation of surface defects has been observed and recorded in TiO2/WO3 and other semiconductor combinations [24][25][26][27][28][29][30]. In addition, titania films are more stable than WO3 films; therefore, the top titania layer provided protection against aggressive electrolytes.…”

Section: Resultsmentioning

confidence: 96%

Photoelectrocatalytic Hydrogen Production Using a TiO2/WO3 Bilayer Photocatalyst in the Presence of Ethanol as a Fuel

et al. 2019

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Photoelectrocatalytic hydrogen production was studied by using a photoelectrochemical cell where the photoanode was made by depositing on FTO electrodes either a nanoparticulate WO3 film alone or a bilayer film made of nanoparticulate WO3 at the bottom covered with a nanoparticulate TiO2 film on the top. Both the electric current and the hydrogen produced by the photoelectrocatalysis cell substantially increased by adding the top titania layer. The presence of this layer did not affect the current-voltage characteristics of the cell (besides the increase of the current density). This was an indication that the flow of electrons in the combined semiconductor photoanode was through the WO3 layer. The increase of the current was mainly attributed to the passivation of the surface recombination sites on WO3 contributing to the limitation of charge recombination mechanisms. In addition, the top titania layer may have contributed to photon absorption by back scattering of light and thus by enhancement of light absorption by WO3. Relatively high charge densities were recorded, owing both to the improvement of the photoanode by the combined photocatalyst and to the presence of ethanol as the sacrificial agent (fuel), which affected the recorded current by “current doubling” phenomena. Hydrogen was produced under electric bias using a simple cathode electrode made of carbon paper carrying carbon black as the electrocatalyst. This electrode gave a Faradaic efficiency of 58% for hydrogen production.

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“…In this photoelectrochemical system, the holes oxidate the wastewater compounds in the photoanode, while the electrons are drawn to the photocathode through the external circuit, where the reduction occurs, producing hydrogen. Very diverse photoanodes have been used in the degradation of wastewater pollutants coupled to hydrogen production including TiO2 [27], TiO2/WO3 [29], TiO2/Pt [28], C-N-TiO2 nanotubes (TiNTs) [30], Bi/BiVO4 [31], g-C3N4 [32], Ti-Fe2O3 [34] and g-C3N4/Ag/AgCl/BiVO4 [35]. Platinum is the most used cathode material, as it has generally shown the best performance as a hydrogen evolution catalyst, with low overpotential and high reaction rates in acidic environments.…”

Section: Pec Generation Of H2 From Wastewatermentioning

confidence: 99%

“…Commonly, studies are performed using small volume (i.e. <100 mL) one compartment reactors; alternatively, other studies use a H-type reactor where the anolyte and catholyte compartments are usually separated by a membrane [29,34]. It has also been proven the possibility of using a filter-press reactor operated in batch recirculation mode [27].…”

Section: Pec Generation Of H2 From Wastewatermentioning

confidence: 99%

New trends on photoelectrocatalysis (PEC): nanomaterials, wastewater treatment and hydrogen generation

Fernández‐Ibáñez¹,

McMichael²,

Rioja-Cabanillas³

et al. 2021

Current Opinion in Chemical Engineering

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Hydrogen production and simultaneous photoelectrocatalytic pollutant oxidation using a TiO2/WO3 nanostructured photoanode under visible light irradiation

Cited by 40 publications

References 26 publications

Semiconductor Electrode Materials Applied in Photoelectrocatalytic Wastewater Treatment—an Overview

Semiconductor Electrode Materials Applied in Photoelectrocatalytic Wastewater Treatment—an Overview

Photoelectrocatalytic Hydrogen Production Using a TiO2/WO3 Bilayer Photocatalyst in the Presence of Ethanol as a Fuel

New trends on photoelectrocatalysis (PEC): nanomaterials, wastewater treatment and hydrogen generation

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