Recent Progress in Metal Oxide-Based Photocatalysts for CO2 Reduction to Solar Fuels: A Review

Li, Xuanzhen; Xiong, Jing; Tang, Zhiling; He, Wenjie; Wang, Yingli; Wang, Xiong; Zhang, Zhao; Wei, Yuechang

doi:10.3390/molecules28041653

Cited by 15 publications

(3 citation statements)

References 145 publications

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“…Since then, numerous materials have been synthesized and investigated for the photocatalytic reduction of CO2. The synthesis of well-defined crystalline oxides has become of interest, since their intrinsic photocatalytic performances are closely related to their exposed facets, where different facets portray different electronic band structures [39,40].…”

Section: Photocatalysismentioning

confidence: 99%

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Talukdar,

Montini

2024

Materials

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Carbon dioxide (CO2) emission has been a global concern over the past few decades due to the increase in the demand of energy, a major source of which is fossil fuels. To mitigate the emission issues, as well as to find a solution for the energy needs, an ample load of research has been carried out over the past few years in CO2 reduction by catalysis. Bismuth, being an active catalyst both photocatalytically and electrocatalytically, is an interesting material that can be formed into oxides, sulphides, oxyhalides, etc. Numerous works have been published based on bismuth-based materials as active catalysts for the reduction of CO2. However, a proper understanding of the behavior of the active facets and the dependence of morphology of the different bismuth-based catalysts is an interesting notion. In this review, various bismuth-based materials will be discussed regarding their activity and charge transfer properties, based on the active facets present in them. With regard to the available literature, a summarization, including photocatalysis, electrocatalysis as well as photoelectrocatalysis, will be detailed, considering various materials with different facets and morphologies. Product selectivity, varying on morphological difference, will also be realized photoelectrochemically.

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Section: Photocatalysismentioning

confidence: 99%

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Talukdar,

Montini

2024

Materials

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“…PCET is important in energy conversion reactions, such as CO 2 reduction (CO 2 RR), oxygen evolution from H 2 O (OER), H 2 evolution (HER), and N 2 reduction (NRR). Each of these involve the transfer of electrons and protons, usually in equal numbers. , Oxides often play a role in these − and other energy applications such as pseudocapacitors and lithium-ion batteries (the last being Li + instead of H + coupled to e – transfer). − …”

Section: Introductionmentioning

confidence: 99%

Photoelectrochemical Proton-Coupled Electron Transfer of TiO₂ Thin Films on Silicon

Nedzbala,

Westbroek,

Margavio

et al. 2024

J. Am. Chem. Soc.

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TiO 2 thin films are often used as protective layers on semiconductors for applications in photovoltaics, molecule− semiconductor hybrid photoelectrodes, and more. Experiments reported here show that TiO 2 thin films on silicon are electrochemically and photoelectrochemically reduced in buffered acetonitrile at potentials relevant to photoelectrocatalysis of CO 2 reduction, N 2 reduction, and H 2 evolution. On both n-type Si and irradiated p-type Si, TiO 2 reduction is proton-coupled with a 1e − :1H + stoichiometry, as demonstrated by the Nernstian dependence of the Ti 4+/3+ E 1/2 on the buffer pK a . Experiments were conducted with and without illumination, and a photovoltage of ∼0.6 V was observed across 20 orders of magnitude in proton activity. The 4 nm films are almost stoichiometrically reduced under mild conditions. The reduced films catalytically transfer protons and electrons to hydrogen atom acceptors, based on cyclic voltammogram, bulk electrolysis, and other mechanistic evidence. TiO 2 /Si thus has the potential to photoelectrochemically generate high-energy H atom carriers. Characterization of the TiO 2 films after reduction reveals restructuring with the formation of islands, rendering TiO 2 films as a potentially poor choice as protecting films or catalyst supports under reducing and protic conditions. Overall, this work demonstrates that atomic layer deposition TiO 2 films on silicon photoelectrodes undergo both chemical and morphological changes upon application of potentials only modestly negative of RHE in these media. While the results should serve as a cautionary tale for researchers aiming to immobilize molecular monolayers on "protective" metal oxides, the robust protoncoupled electron transfer reactivity of the films introduces opportunities for the photoelectrochemical generation of reactive chargecarrying mediators.

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“…To address the thermodynamic problem of CO 2 activation, different approaches have been explored from the early 1970s; different methodologies have been studied so far, including different energy vectors such as electricity, heat and photons [10][11][12]. Moreover, different classes of catalysts, including metal oxides, perovskites, metal-organic frameworks (MOFs), MXenes, metal complexes and many others [13][14][15][16], are currently under investigation. From the large plethora of catalytic processes studied so far, the photocatalytic pathway has produced interesting results: using solar light as an energy vector greatly reduces the environmental impact of the process, as the energy source that drives the reaction is sustainable and readily available [17].…”

Section: Introductionmentioning

confidence: 99%

Cu-Doped SrTiO3 Nanostructured Catalysts for CO2 Conversion into Solar Fuels Using Localised Surface Plasmon Resonance

Rizzato,

Cavazzani,

Osti

et al. 2023

Catalysts

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Carbon dioxide valorisation is one of the most discussed topics amongst researchers; indeed, finding a way to significantly reduce CO2 concentration in the atmosphere is crucial in order to mitigate climate change effects in the next decades. In this study, SrTiO3-supported Cu nanoparticles are exploited as Localised Surface Plasmon Resonance (LSPR)-mediated catalysts for CO2 reduction. The materials were prepared via sol–gel citrate route methodology, inserting Cu as a dopant in the perovskite structure; reducing treatments at different temperatures were performed to promote copper atom exsolution, thus forming nanostructures upon the surface. The perovskitic structure was confirmed via ex situ and operando XRD analysis, while compositional analysis was carried out through XPS and EDS; SEM and TEM images revealed morphological changes with different reducing treatments, and bulk reducibility was analysed with H2-TPR, revealing different Cu species in the material. Band gap analysis via DRS showed the successful incorporation of copper in the perovskite, affecting the light absorption properties. Finally, catalytic tests showed that copper nanoparticles play a role in CO2 activation with sunlight, proving that LSPR could be exploited for catalytic means.

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Recent Progress in Metal Oxide-Based Photocatalysts for CO2 Reduction to Solar Fuels: A Review

Cited by 15 publications

References 145 publications

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Photoelectrochemical Proton-Coupled Electron Transfer of TiO₂ Thin Films on Silicon

Cu-Doped SrTiO3 Nanostructured Catalysts for CO2 Conversion into Solar Fuels Using Localised Surface Plasmon Resonance

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Recent Progress in Metal Oxide-Based Photocatalysts for CO2 Reduction to Solar Fuels: A Review

Cited by 15 publications

References 145 publications

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Role of Facets and Morphologies of Different Bismuth-Based Materials for CO2 Reduction to Fuels

Photoelectrochemical Proton-Coupled Electron Transfer of TiO2 Thin Films on Silicon

Cu-Doped SrTiO3 Nanostructured Catalysts for CO2 Conversion into Solar Fuels Using Localised Surface Plasmon Resonance

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Photoelectrochemical Proton-Coupled Electron Transfer of TiO₂ Thin Films on Silicon