Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Wegdan Ramadan
  • Ralf Dillert
  • Julian Koch
  • Christoph Tegenkamp
  • Detlef Bahnemann

External Research Organisations

  • Alexandria University
  • Saint Petersburg State University
View graph of relations

Details

Original languageEnglish
Pages (from-to)22-29
Number of pages8
JournalCatalysis today
Volume326
Early online date24 Sept 2018
Publication statusPublished - Apr 2019

Abstract

BiFeO 3 nanoparticles were synthesized using a sol gel method and its photocatalytic ability for formic acid reformation is reported, for the first time, focusing on the BiFeO 3 stability after photocatalytic reaction at ∼ pH 3. Reformation of formic acid in O 2-free aqueous suspensions was found to result in the evolution of CO 2 and H 2 gases. However, the expected molar ratio of 1:1 was not evolved. Significantly lower amounts of H 2 than expected were detected. The position of the conduction band of BiFeO 3 resides well below the reduction potential of the protons to form molecular H 2, hence it is anticipated that the photoexcited electrons react mainly with other species being present in the reactor, probably the photocatalyst itself. To assess the changes occurring in the photocatalyst, bulk and surface analysis before and after the photocatalytic reaction were performed using different techniques. XRD revealed changes occurring in the bulk of the photocatalyst such as leaching of most of the impurity phases accompanied by the relaxation of the strained lattice to its ideal position. From XPS, the ratio between Fe 3+: Fe 2+ before and after photocatalytic reaction with formic acid was found to be 86:14 and 64:36, respectively, thus evincing a reduction process of Fe 3+ by the photo generated electrons in the conduction band that were unable to reduce H + into H 2. Leaching of Fe and, to less extent, Bi ions into the solution after reaction was recorded. From the fitted XPS, the nominal composition of BFO was calculated to be Bi 1Fe 0.9O 2.9 and Bi 1Fe 0.71O 2.7 before and after the photocatalytic reaction. The results presented in this work signify the importance of addressing bulk and surface stability of iron-based photocatalysts to ensure long-term usability.

Keywords

    Bismuth iron oxide, Formic acid, Iron-based compounds, Photocatalysis, Stability, XPS

ASJC Scopus subject areas

Cite this

Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid. / Ramadan, Wegdan; Dillert, Ralf; Koch, Julian et al.
In: Catalysis today, Vol. 326, 04.2019, p. 22-29.

Research output: Contribution to journalArticleResearchpeer review

Ramadan W, Dillert R, Koch J, Tegenkamp C, Bahnemann D. Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid. Catalysis today. 2019 Apr;326:22-29. Epub 2018 Sept 24. doi: 10.1016/j.cattod.2018.09.003
Ramadan, Wegdan ; Dillert, Ralf ; Koch, Julian et al. / Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid. In: Catalysis today. 2019 ; Vol. 326. pp. 22-29.
Download
@article{784d643335cd427599d1e14a5e6a37d1,
title = "Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid",
abstract = "BiFeO 3 nanoparticles were synthesized using a sol gel method and its photocatalytic ability for formic acid reformation is reported, for the first time, focusing on the BiFeO 3 stability after photocatalytic reaction at ∼ pH 3. Reformation of formic acid in O 2-free aqueous suspensions was found to result in the evolution of CO 2 and H 2 gases. However, the expected molar ratio of 1:1 was not evolved. Significantly lower amounts of H 2 than expected were detected. The position of the conduction band of BiFeO 3 resides well below the reduction potential of the protons to form molecular H 2, hence it is anticipated that the photoexcited electrons react mainly with other species being present in the reactor, probably the photocatalyst itself. To assess the changes occurring in the photocatalyst, bulk and surface analysis before and after the photocatalytic reaction were performed using different techniques. XRD revealed changes occurring in the bulk of the photocatalyst such as leaching of most of the impurity phases accompanied by the relaxation of the strained lattice to its ideal position. From XPS, the ratio between Fe 3+: Fe 2+ before and after photocatalytic reaction with formic acid was found to be 86:14 and 64:36, respectively, thus evincing a reduction process of Fe 3+ by the photo generated electrons in the conduction band that were unable to reduce H + into H 2. Leaching of Fe and, to less extent, Bi ions into the solution after reaction was recorded. From the fitted XPS, the nominal composition of BFO was calculated to be Bi 1Fe 0.9O 2.9 and Bi 1Fe 0.71O 2.7 before and after the photocatalytic reaction. The results presented in this work signify the importance of addressing bulk and surface stability of iron-based photocatalysts to ensure long-term usability. ",
keywords = "Bismuth iron oxide, Formic acid, Iron-based compounds, Photocatalysis, Stability, XPS",
author = "Wegdan Ramadan and Ralf Dillert and Julian Koch and Christoph Tegenkamp and Detlef Bahnemann",
note = "Funding information: Wegdan Ramadan would like to express gratitude to the Alexander von Humboldt Foundation , for a fellowship. We appreciate the help received from Arsou Arimi in performing the last two experiments. Finally, we are grateful to Prof. Dr. Carla Vogt and Mrs. Stella Kittel for the atomic emission spectrometer with inductively coupled plasma measurements.",
year = "2019",
month = apr,
doi = "10.1016/j.cattod.2018.09.003",
language = "English",
volume = "326",
pages = "22--29",
journal = "Catalysis today",
issn = "0920-5861",
publisher = "Elsevier",

}

Download

TY - JOUR

T1 - Changes in the solid-state properties of bismuth iron oxide during the photocatalytic reformation of formic acid

AU - Ramadan, Wegdan

AU - Dillert, Ralf

AU - Koch, Julian

AU - Tegenkamp, Christoph

AU - Bahnemann, Detlef

N1 - Funding information: Wegdan Ramadan would like to express gratitude to the Alexander von Humboldt Foundation , for a fellowship. We appreciate the help received from Arsou Arimi in performing the last two experiments. Finally, we are grateful to Prof. Dr. Carla Vogt and Mrs. Stella Kittel for the atomic emission spectrometer with inductively coupled plasma measurements.

PY - 2019/4

Y1 - 2019/4

N2 - BiFeO 3 nanoparticles were synthesized using a sol gel method and its photocatalytic ability for formic acid reformation is reported, for the first time, focusing on the BiFeO 3 stability after photocatalytic reaction at ∼ pH 3. Reformation of formic acid in O 2-free aqueous suspensions was found to result in the evolution of CO 2 and H 2 gases. However, the expected molar ratio of 1:1 was not evolved. Significantly lower amounts of H 2 than expected were detected. The position of the conduction band of BiFeO 3 resides well below the reduction potential of the protons to form molecular H 2, hence it is anticipated that the photoexcited electrons react mainly with other species being present in the reactor, probably the photocatalyst itself. To assess the changes occurring in the photocatalyst, bulk and surface analysis before and after the photocatalytic reaction were performed using different techniques. XRD revealed changes occurring in the bulk of the photocatalyst such as leaching of most of the impurity phases accompanied by the relaxation of the strained lattice to its ideal position. From XPS, the ratio between Fe 3+: Fe 2+ before and after photocatalytic reaction with formic acid was found to be 86:14 and 64:36, respectively, thus evincing a reduction process of Fe 3+ by the photo generated electrons in the conduction band that were unable to reduce H + into H 2. Leaching of Fe and, to less extent, Bi ions into the solution after reaction was recorded. From the fitted XPS, the nominal composition of BFO was calculated to be Bi 1Fe 0.9O 2.9 and Bi 1Fe 0.71O 2.7 before and after the photocatalytic reaction. The results presented in this work signify the importance of addressing bulk and surface stability of iron-based photocatalysts to ensure long-term usability.

AB - BiFeO 3 nanoparticles were synthesized using a sol gel method and its photocatalytic ability for formic acid reformation is reported, for the first time, focusing on the BiFeO 3 stability after photocatalytic reaction at ∼ pH 3. Reformation of formic acid in O 2-free aqueous suspensions was found to result in the evolution of CO 2 and H 2 gases. However, the expected molar ratio of 1:1 was not evolved. Significantly lower amounts of H 2 than expected were detected. The position of the conduction band of BiFeO 3 resides well below the reduction potential of the protons to form molecular H 2, hence it is anticipated that the photoexcited electrons react mainly with other species being present in the reactor, probably the photocatalyst itself. To assess the changes occurring in the photocatalyst, bulk and surface analysis before and after the photocatalytic reaction were performed using different techniques. XRD revealed changes occurring in the bulk of the photocatalyst such as leaching of most of the impurity phases accompanied by the relaxation of the strained lattice to its ideal position. From XPS, the ratio between Fe 3+: Fe 2+ before and after photocatalytic reaction with formic acid was found to be 86:14 and 64:36, respectively, thus evincing a reduction process of Fe 3+ by the photo generated electrons in the conduction band that were unable to reduce H + into H 2. Leaching of Fe and, to less extent, Bi ions into the solution after reaction was recorded. From the fitted XPS, the nominal composition of BFO was calculated to be Bi 1Fe 0.9O 2.9 and Bi 1Fe 0.71O 2.7 before and after the photocatalytic reaction. The results presented in this work signify the importance of addressing bulk and surface stability of iron-based photocatalysts to ensure long-term usability.

KW - Bismuth iron oxide

KW - Formic acid

KW - Iron-based compounds

KW - Photocatalysis

KW - Stability

KW - XPS

UR - http://www.scopus.com/inward/record.url?scp=85054149181&partnerID=8YFLogxK

U2 - 10.1016/j.cattod.2018.09.003

DO - 10.1016/j.cattod.2018.09.003

M3 - Article

VL - 326

SP - 22

EP - 29

JO - Catalysis today

JF - Catalysis today

SN - 0920-5861

ER -