Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory
Two-dimensional (2D) gallium selenide (GaSe) is known for its inert surface and wide bandgap, limiting its application as a photocatalytic material for the hydrogen evolution reaction (HER). Partial substitution of Se with O atoms can improve its catalytic efficiency. This work discovered that the s...
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my.um.eprints.417302025-01-17T07:13:26Z http://eprints.um.edu.my/41730/ Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory Demissie, Ephrem G. Tang, Wai Kit Siu, Chi-Kit QD Chemistry Two-dimensional (2D) gallium selenide (GaSe) is known for its inert surface and wide bandgap, limiting its application as a photocatalytic material for the hydrogen evolution reaction (HER). Partial substitution of Se with O atoms can improve its catalytic efficiency. This work discovered that the surface activity of the substitutional O-doped single-layer GaSe surfaces (GaSe1-xOx, for x <= 22%) and their bandgap sizes are dependent on the detailed atomic configuration of the dopants, as revealed from density functional theory. For GaSe1-xOx at low O contents, where all O atoms are favorably separated by at least one-GaSe-Ga- unit, the surface activity for the HER is insignificantly improved by increasing dopant concentration. By contrast, when more O dopants are available and arranged in adjacent positions (O-Ga-O), the hydrogen adsorption efficiency of GaSe1-xOx increases and their bandgaps are reduced with increasing dopant concentration. These important features are attributed to weakening of the Ga-O covalent interaction in these more localized dopant arrangements, which in turn strengthens the O-H bonds. This weakened Ga-O covalent bond also descends the conduction band minimum toward the Fermi level, resulting in bandgap reduction and thus favoring visible-light absorption. Optimal atomic configurations (all having localized O-dopant arrangements) have been identified, and they exhibit almost thermoneutral hydrogen adsorption free energy Delta G(H) and small bandgaps (2.09-2.21 eV), making them promising materials to perform an efficient HER. Fine-tuning the Ga-O interaction by applying tensile strength T-s parallel to the 2D surface of up to 1% further reduces their bandgaps to 1.95-2.05 eV. Our theoretical predictions suggest that controlling the atomic configuration of dopants provides opportunities for engineering single-layered GaSe1-xOx materials with surface reactivity and bandgaps that suit photocatalytic water splitting. American Chemical Society 2022-05 Article PeerReviewed Demissie, Ephrem G. and Tang, Wai Kit and Siu, Chi-Kit (2022) Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory. ACS Applied Energy Materials, 5 (5). pp. 6070-6079. ISSN 2574-0962, DOI https://doi.org/10.1021/acsaem.2c00472 <https://doi.org/10.1021/acsaem.2c00472>. https://doi.org/10.1021/acsaem.2c00472 10.1021/acsaem.2c00472 |
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QD Chemistry Demissie, Ephrem G. Tang, Wai Kit Siu, Chi-Kit Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
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Two-dimensional (2D) gallium selenide (GaSe) is known for its inert surface and wide bandgap, limiting its application as a photocatalytic material for the hydrogen evolution reaction (HER). Partial substitution of Se with O atoms can improve its catalytic efficiency. This work discovered that the surface activity of the substitutional O-doped single-layer GaSe surfaces (GaSe1-xOx, for x <= 22%) and their bandgap sizes are dependent on the detailed atomic configuration of the dopants, as revealed from density functional theory. For GaSe1-xOx at low O contents, where all O atoms are favorably separated by at least one-GaSe-Ga- unit, the surface activity for the HER is insignificantly improved by increasing dopant concentration. By contrast, when more O dopants are available and arranged in adjacent positions (O-Ga-O), the hydrogen adsorption efficiency of GaSe1-xOx increases and their bandgaps are reduced with increasing dopant concentration. These important features are attributed to weakening of the Ga-O covalent interaction in these more localized dopant arrangements, which in turn strengthens the O-H bonds. This weakened Ga-O covalent bond also descends the conduction band minimum toward the Fermi level, resulting in bandgap reduction and thus favoring visible-light absorption. Optimal atomic configurations (all having localized O-dopant arrangements) have been identified, and they exhibit almost thermoneutral hydrogen adsorption free energy Delta G(H) and small bandgaps (2.09-2.21 eV), making them promising materials to perform an efficient HER. Fine-tuning the Ga-O interaction by applying tensile strength T-s parallel to the 2D surface of up to 1% further reduces their bandgaps to 1.95-2.05 eV. Our theoretical predictions suggest that controlling the atomic configuration of dopants provides opportunities for engineering single-layered GaSe1-xOx materials with surface reactivity and bandgaps that suit photocatalytic water splitting. |
| format |
Article |
| author |
Demissie, Ephrem G. Tang, Wai Kit Siu, Chi-Kit |
| author_facet |
Demissie, Ephrem G. Tang, Wai Kit Siu, Chi-Kit |
| author_sort |
Demissie, Ephrem G. |
| title |
Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
| title_short |
Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
| title_full |
Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
| title_fullStr |
Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
| title_full_unstemmed |
Structure-Property Relationship of Oxygen-Doped Two-Dimensional Gallium Selenide for Hydrogen Evolution Reaction Revealed from Density Functional Theory |
| title_sort |
structure-property relationship of oxygen-doped two-dimensional gallium selenide for hydrogen evolution reaction revealed from density functional theory |
| publisher |
American Chemical Society |
| publishDate |
2022 |
| url |
http://eprints.um.edu.my/41730/ https://doi.org/10.1021/acsaem.2c00472 |
| _version_ |
1825160584754102272 |
| score |
13.239859 |