Reduction of nitrate to ammonia using photocatalytically accumulated electrons on titanium(IV) oxide in a time-separated redox reaction

[Display omitted] •Reduction of NO3− to ammonia NH3 was performed by a time-separated redox reaction.•The reaction uses a two-step reaction under the control of photoexcitation an electron acceptor.•Eight-electron reduction of NO3− to NH3 was performed by accumulated electrons in a TiO2 suspension.•...

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Published inInorganic chemistry communications Vol. 141; p. 109585
Main Authors Murakami, Naoya, Suenaga, Masato, Deguchi, Ryota
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.07.2022
Subjects
Ammonia
Electron accumulation
Photocatalyst
Titanium(IV) oxide
Titanium(IV) oxide
Ammonia
Electron accumulation
Photocatalyst
Online AccessGet full text
ISSN1387-7003
1879-0259
1879-0259
DOI10.1016/j.inoche.2022.109585

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Abstract [Display omitted] •Reduction of NO3− to ammonia NH3 was performed by a time-separated redox reaction.•The reaction uses a two-step reaction under the control of photoexcitation an electron acceptor.•Eight-electron reduction of NO3− to NH3 was performed by accumulated electrons in a TiO2 suspension.•The use of a rutile sample with a large number of defective sites is a key factor for the reaction. Reduction of nitrate (NO3−) to ammonia (NH3) was performed by a time-separated redox reaction using photocatalytically accumulated electrons in a titanium(IV) oxide (TiO2) suspension. The time-separated redox reaction uses a two-step reaction under the control of photoexcitation and an electron acceptor: (1) accumulation of electrons in TiO2 powder under photoexcitation and (2) reduction of added NO3− by accumulated electrons in the dark. Color change of TiO2 depending on the degree of electron accumulation was observed during the reaction, and 8-electron reduction of NO3− to NH3 was performed by accumulated electrons. The results of the time-separated redox reaction using 10 kinds of commercial TiO2 powder indicate that the use of a rutile sample with a large number of trivalent titanium species is a key factor for NH3 production.
AbstractList [Display omitted] •Reduction of NO3− to ammonia NH3 was performed by a time-separated redox reaction.•The reaction uses a two-step reaction under the control of photoexcitation an electron acceptor.•Eight-electron reduction of NO3− to NH3 was performed by accumulated electrons in a TiO2 suspension.•The use of a rutile sample with a large number of defective sites is a key factor for the reaction. Reduction of nitrate (NO3−) to ammonia (NH3) was performed by a time-separated redox reaction using photocatalytically accumulated electrons in a titanium(IV) oxide (TiO2) suspension. The time-separated redox reaction uses a two-step reaction under the control of photoexcitation and an electron acceptor: (1) accumulation of electrons in TiO2 powder under photoexcitation and (2) reduction of added NO3− by accumulated electrons in the dark. Color change of TiO2 depending on the degree of electron accumulation was observed during the reaction, and 8-electron reduction of NO3− to NH3 was performed by accumulated electrons. The results of the time-separated redox reaction using 10 kinds of commercial TiO2 powder indicate that the use of a rutile sample with a large number of trivalent titanium species is a key factor for NH3 production.
ArticleNumber 109585
Author Murakami, Naoya
Suenaga, Masato
Deguchi, Ryota
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Keywords Titanium(IV) oxide
Ammonia
Electron accumulation
Photocatalyst
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Snippet [Display omitted] •Reduction of NO3− to ammonia NH3 was performed by a time-separated redox reaction.•The reaction uses a two-step reaction under the control...
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StartPage 109585
SubjectTerms Ammonia
Electron accumulation
Photocatalyst
Titanium(IV) oxide
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Title Reduction of nitrate to ammonia using photocatalytically accumulated electrons on titanium(IV) oxide in a time-separated redox reaction
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