Charge Carriers Cascade in a Ternary TiO2/TiO2/ZnS Heterojunction: A DFT Study

Composite materials whose band alignment induces a favorable separation of photogenerated electrons and holes often reveal a stronger photocatalytic activity compared to their separate components. As shown by experiments, titania composites display a heterojunction between the anatase (101)‐(001) su...

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Veröffentlicht in:	ChemCatChem 2020-04, Vol.12 (7), p.2097-2105
Hauptverfasser:	Di Liberto, Giovanni, Tosoni, Sergio, Pacchioni, Gianfranco
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Sprache:	eng
Schlagworte:	Anatase Catalytic activity charge-carriers separation Composite materials Computational Chemistry Current carriers Electrons heterojunction Heterojunctions Photocatalysis polaron Separation TiO2 Titanium dioxide ZnS
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creator	Di Liberto, Giovanni Tosoni, Sergio Pacchioni, Gianfranco
description	Composite materials whose band alignment induces a favorable separation of photogenerated electrons and holes often reveal a stronger photocatalytic activity compared to their separate components. As shown by experiments, titania composites display a heterojunction between the anatase (101)‐(001) surfaces, where the former stabilizes electrons and the latter the holes. In principle, an even more efficient carriers separation is achieved if a third component with high hole‐stabilizing capability, ZnS(110), is growth on anatase (001). However, even though this ternary TiO2/TiO2/ZnS composite material displays good photoactivity, it does not overperform the TiO2/TiO2 one. In this paper an explanation of this evidence is provided by means of periodic hybrid DFT calculations, showing how Coulomb forces play a role against the separation of charge carriers predicted based on the relative energy of the band edges. This highlights the necessity to explicitly account for structural and electronic junction's effects, as well as charge carriers’ localization. Getting the band back together: In the bottom is reported the band alignment of three independent units, TiO2 (101), TiO2 (001), ZnS (110). In the top is reported the favorable charge‐carriers location, while the further migration of the e− increases the energy of the system.
doi_str_mv	10.1002/cctc.201902351
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As shown by experiments, titania composites display a heterojunction between the anatase (101)‐(001) surfaces, where the former stabilizes electrons and the latter the holes. In principle, an even more efficient carriers separation is achieved if a third component with high hole‐stabilizing capability, ZnS(110), is growth on anatase (001). However, even though this ternary TiO2/TiO2/ZnS composite material displays good photoactivity, it does not overperform the TiO2/TiO2 one. In this paper an explanation of this evidence is provided by means of periodic hybrid DFT calculations, showing how Coulomb forces play a role against the separation of charge carriers predicted based on the relative energy of the band edges. This highlights the necessity to explicitly account for structural and electronic junction's effects, as well as charge carriers’ localization. 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As shown by experiments, titania composites display a heterojunction between the anatase (101)‐(001) surfaces, where the former stabilizes electrons and the latter the holes. In principle, an even more efficient carriers separation is achieved if a third component with high hole‐stabilizing capability, ZnS(110), is growth on anatase (001). However, even though this ternary TiO2/TiO2/ZnS composite material displays good photoactivity, it does not overperform the TiO2/TiO2 one. In this paper an explanation of this evidence is provided by means of periodic hybrid DFT calculations, showing how Coulomb forces play a role against the separation of charge carriers predicted based on the relative energy of the band edges. This highlights the necessity to explicitly account for structural and electronic junction's effects, as well as charge carriers’ localization. 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subjects	Anatase Catalytic activity charge-carriers separation Composite materials Computational Chemistry Current carriers Electrons heterojunction Heterojunctions Photocatalysis polaron Separation TiO2 Titanium dioxide ZnS
title	Charge Carriers Cascade in a Ternary TiO2/TiO2/ZnS Heterojunction: A DFT Study
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