Silver-inserted heterojunction photocatalyst consisting of zinc rhodium oxide and silver antimony oxide for overall pure-water splitting under visible light

Silver-inserted heterojunction photocatalyst consisting of zinc rhodium oxide and silver antimony oxide for overall pure-water splitting under visible light

[Display omitted] •We established a hetero-junction photocatalyst for overall pure-water splitting.•The photocatalyst is a solid-state Ag-inserted ZnRh2O4 andAgSbO3.•Ammonia and hydrogen peroxide treatments to remove excess Ag is required.•The photocatalyst is capable of utilizing visible at wavelen...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Vol. 209; pp. 663 - 668
Main Authors: Hara, Yoshiki, Takashima, Toshihiro, Kobayashi, Ryoya, Abeyrathna, Sameera, Ohtani, Bunsho, Irie, Hiroshi
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 15-07-2017
Elsevier BV
Subjects:
Ammonia treatment
Ammonium
Ammonium hydroxide
Antimony
Antimony oxides
Chemical reactions
Hydrogen peroxide
Irradiation
Light irradiation
Nitric acid
Photocatalysis
Photocatalysts
Radiation
Rhodium
Silver
Silver antimony oxide
Studies
Two-step overall water-splitting
Water splitting
Wavelengths
Zinc oxide
Zinc rhodium oxide
Two-step overall water-splitting
Silver
Ammonia treatment
Silver antimony oxide
Zinc rhodium oxide
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Summary:[Display omitted] •We established a hetero-junction photocatalyst for overall pure-water splitting.•The photocatalyst is a solid-state Ag-inserted ZnRh2O4 andAgSbO3.•Ammonia and hydrogen peroxide treatments to remove excess Ag is required.•The photocatalyst is capable of utilizing visible at wavelengths up to 660nm. Overall pure-water splitting under visible-light irradiation at wavelengths up to 660nm was accomplished utilizing a solid-state hetero-junction photocatalyst following the Z-scheme mechanism in which zinc rhodium oxide (ZnRh2O4) and silver antimony oxide (AgSbO3) as hydrogen (H2)- and oxygen (O2)-evolution photocatalysts, respectively, were connected with silver (Ag, ZnRh2O4/Ag/AgSbO3). In our previous paper (Kobayashi et al., J. Phys. Chem. C, 118 (2014) 22450–22456), nitric acid (HNO3) treatment of mixtures of AgSbO3, Ag2O, and ZnRh2O4 after calcination formed defective AgSbO3 (Ag1-xSbO3-y) and the resulting photocatalyst, ZnRh2O4/Ag/Ag1-xSbO3-y, exhibited reduced visible-light wavelength sensitivity (up to 545nm) and overall water-splitting activity. To overcome this limitation, here, unnecessary Ag was removed by treatment with ammonium hydroxide (NH4OH) and hydrogen peroxide (H2O2), which resulted in the successful formation of ZnRh2O4/Ag/AgSbO3. This photocatalyst was capable of utilizing visible light at wavelengths up to 660nm and exhibited enhanced overall water-splitting activity. The synthesis approach described in this study represents a novel and facile method for preparing visible-light sensitive heterojunction photocatalysts connected with Ag.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2017.03.040