Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results

Research output: Contribution to journalArticleResearchpeer review

Authors

  • A.C. Ulpe
  • K.C.L. Bauerfeind
  • L.I. Granone
  • A. Arimi
  • L. Megatif
  • R. Dillert
  • S. Warfsmann
  • D.H. Taffa
  • M. Wark
  • D.W. Bahnemann
  • T. Bredow

Research Organisations

External Research Organisations

  • University of Bonn
  • Carl von Ossietzky University of Oldenburg
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Details

Original languageEnglish
Pages (from-to)719-776
Number of pages58
JournalZeitschrift fur Physikalische Chemie
Volume234
Issue number4
Early online date19 Dec 2019
Publication statusPublished - 28 Apr 2020

Abstract

This paper gives an overview about recent theoretical and experimental work on electronic and optical properties of spinel ferrites MFe 2O 4. These compounds have come into focus of research due to their possible application as photocatalyst material for photoelectrochemical water splitting. The theoretical background of state-of-the-art quantum-chemical approaches applied for predicting electronic and optical band gaps, absolute band positions, optical absorption spectra, dielectric functions and Raman spectra, is briefly reviewed. Recent applications of first-principles methods on magnetic and electronic properties of ferrites with M = Mg and the first row of subgroup elements Sc to Zn are presented, where it is shown that the fundamental band gap is strongly dependent on the spin state and the degree of inversion of the spinel structure. The observed variation of electronic properties may serve as an explanation for the large scattering of experimental results. The exchange of M and Fe cations has also a pronounced effect on the Raman spectra of ferrites, which is analyzed at atomic scale from first principles. Calculated optical absorption spectra of ferrites are compared to experimental spectra. The electronic nature of the first excitations and the role of oxygen vacancies are discussed. For the calculation of absolute band positions, which have a significant impact on the photoelectrochemical activity of the ferrites, models of the most stable ferrite surfaces are developed that take into account their polar nature and the interaction with the solvent. Theoretically predicted valence and conduction band edges are compared to results from electrochemical measurements. The role of cation exchange on the surface electronic structure is investigated both theoretically and experimentally.

Keywords

    DFT, perturbation theory, photoelectrochemical water splitting, spectroscopy, spinel ferrites

ASJC Scopus subject areas

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Cite this

Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results. / Ulpe, A.C.; Bauerfeind, K.C.L.; Granone, L.I. et al.
In: Zeitschrift fur Physikalische Chemie, Vol. 234, No. 4, 28.04.2020, p. 719-776.

Research output: Contribution to journalArticleResearchpeer review

Ulpe, AC, Bauerfeind, KCL, Granone, LI, Arimi, A, Megatif, L, Dillert, R, Warfsmann, S, Taffa, DH, Wark, M, Bahnemann, DW & Bredow, T 2020, 'Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results', Zeitschrift fur Physikalische Chemie, vol. 234, no. 4, pp. 719-776. https://doi.org/10.1515/zpch-2019-1449
Ulpe, A. C., Bauerfeind, K. C. L., Granone, L. I., Arimi, A., Megatif, L., Dillert, R., Warfsmann, S., Taffa, D. H., Wark, M., Bahnemann, D. W., & Bredow, T. (2020). Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results. Zeitschrift fur Physikalische Chemie, 234(4), 719-776. https://doi.org/10.1515/zpch-2019-1449
Ulpe AC, Bauerfeind KCL, Granone LI, Arimi A, Megatif L, Dillert R et al. Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results. Zeitschrift fur Physikalische Chemie. 2020 Apr 28;234(4):719-776. Epub 2019 Dec 19. doi: 10.1515/zpch-2019-1449
Ulpe, A.C. ; Bauerfeind, K.C.L. ; Granone, L.I. et al. / Photoelectrochemistry of Ferrites : Theoretical Predictions vs. Experimental Results. In: Zeitschrift fur Physikalische Chemie. 2020 ; Vol. 234, No. 4. pp. 719-776.
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title = "Photoelectrochemistry of Ferrites: Theoretical Predictions vs. Experimental Results",
abstract = "This paper gives an overview about recent theoretical and experimental work on electronic and optical properties of spinel ferrites MFe 2O 4. These compounds have come into focus of research due to their possible application as photocatalyst material for photoelectrochemical water splitting. The theoretical background of state-of-the-art quantum-chemical approaches applied for predicting electronic and optical band gaps, absolute band positions, optical absorption spectra, dielectric functions and Raman spectra, is briefly reviewed. Recent applications of first-principles methods on magnetic and electronic properties of ferrites with M = Mg and the first row of subgroup elements Sc to Zn are presented, where it is shown that the fundamental band gap is strongly dependent on the spin state and the degree of inversion of the spinel structure. The observed variation of electronic properties may serve as an explanation for the large scattering of experimental results. The exchange of M and Fe cations has also a pronounced effect on the Raman spectra of ferrites, which is analyzed at atomic scale from first principles. Calculated optical absorption spectra of ferrites are compared to experimental spectra. The electronic nature of the first excitations and the role of oxygen vacancies are discussed. For the calculation of absolute band positions, which have a significant impact on the photoelectrochemical activity of the ferrites, models of the most stable ferrite surfaces are developed that take into account their polar nature and the interaction with the solvent. Theoretically predicted valence and conduction band edges are compared to results from electrochemical measurements. The role of cation exchange on the surface electronic structure is investigated both theoretically and experimentally. ",
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author = "A.C. Ulpe and K.C.L. Bauerfeind and L.I. Granone and A. Arimi and L. Megatif and R. Dillert and S. Warfsmann and D.H. Taffa and M. Wark and D.W. Bahnemann and T. Bredow",
note = "Funding information: We gratefully acknowledge financial support by the Deutsche Forschungsgemeinschaft within the priority program SPP 1613 {\textquoteleft}Fuels Produced Regeneratively Through Light-Driven Water Splitting: Clarification of the Elemental Processes Involved and Prospects for Implementation in Technological Concepts{\textquoteright} (BR 1768/9-1, BA 1137/22-1, WA 1116/28). The authors A. Ulpe, K. C. L. Bauerfeind and T. Bredow thank the Paderborn Center for Parallel Computing, PC2, and the Leibniz University IT Services (former Regionales Rechenzentrum f{\"u}r Niedersachsen [RRZN]) for providing computational resources. A. Ulpe thankfully acknowledges the financial support by the International Max Planck Research School on Reactive Structure Analysis for Chemical Reactions (IMPRS-RECHARGE).",
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T2 - Theoretical Predictions vs. Experimental Results

AU - Ulpe, A.C.

AU - Bauerfeind, K.C.L.

AU - Granone, L.I.

AU - Arimi, A.

AU - Megatif, L.

AU - Dillert, R.

AU - Warfsmann, S.

AU - Taffa, D.H.

AU - Wark, M.

AU - Bahnemann, D.W.

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N1 - Funding information: We gratefully acknowledge financial support by the Deutsche Forschungsgemeinschaft within the priority program SPP 1613 ‘Fuels Produced Regeneratively Through Light-Driven Water Splitting: Clarification of the Elemental Processes Involved and Prospects for Implementation in Technological Concepts’ (BR 1768/9-1, BA 1137/22-1, WA 1116/28). The authors A. Ulpe, K. C. L. Bauerfeind and T. Bredow thank the Paderborn Center for Parallel Computing, PC2, and the Leibniz University IT Services (former Regionales Rechenzentrum für Niedersachsen [RRZN]) for providing computational resources. A. Ulpe thankfully acknowledges the financial support by the International Max Planck Research School on Reactive Structure Analysis for Chemical Reactions (IMPRS-RECHARGE).

PY - 2020/4/28

Y1 - 2020/4/28

N2 - This paper gives an overview about recent theoretical and experimental work on electronic and optical properties of spinel ferrites MFe 2O 4. These compounds have come into focus of research due to their possible application as photocatalyst material for photoelectrochemical water splitting. The theoretical background of state-of-the-art quantum-chemical approaches applied for predicting electronic and optical band gaps, absolute band positions, optical absorption spectra, dielectric functions and Raman spectra, is briefly reviewed. Recent applications of first-principles methods on magnetic and electronic properties of ferrites with M = Mg and the first row of subgroup elements Sc to Zn are presented, where it is shown that the fundamental band gap is strongly dependent on the spin state and the degree of inversion of the spinel structure. The observed variation of electronic properties may serve as an explanation for the large scattering of experimental results. The exchange of M and Fe cations has also a pronounced effect on the Raman spectra of ferrites, which is analyzed at atomic scale from first principles. Calculated optical absorption spectra of ferrites are compared to experimental spectra. The electronic nature of the first excitations and the role of oxygen vacancies are discussed. For the calculation of absolute band positions, which have a significant impact on the photoelectrochemical activity of the ferrites, models of the most stable ferrite surfaces are developed that take into account their polar nature and the interaction with the solvent. Theoretically predicted valence and conduction band edges are compared to results from electrochemical measurements. The role of cation exchange on the surface electronic structure is investigated both theoretically and experimentally.

AB - This paper gives an overview about recent theoretical and experimental work on electronic and optical properties of spinel ferrites MFe 2O 4. These compounds have come into focus of research due to their possible application as photocatalyst material for photoelectrochemical water splitting. The theoretical background of state-of-the-art quantum-chemical approaches applied for predicting electronic and optical band gaps, absolute band positions, optical absorption spectra, dielectric functions and Raman spectra, is briefly reviewed. Recent applications of first-principles methods on magnetic and electronic properties of ferrites with M = Mg and the first row of subgroup elements Sc to Zn are presented, where it is shown that the fundamental band gap is strongly dependent on the spin state and the degree of inversion of the spinel structure. The observed variation of electronic properties may serve as an explanation for the large scattering of experimental results. The exchange of M and Fe cations has also a pronounced effect on the Raman spectra of ferrites, which is analyzed at atomic scale from first principles. Calculated optical absorption spectra of ferrites are compared to experimental spectra. The electronic nature of the first excitations and the role of oxygen vacancies are discussed. For the calculation of absolute band positions, which have a significant impact on the photoelectrochemical activity of the ferrites, models of the most stable ferrite surfaces are developed that take into account their polar nature and the interaction with the solvent. Theoretically predicted valence and conduction band edges are compared to results from electrochemical measurements. The role of cation exchange on the surface electronic structure is investigated both theoretically and experimentally.

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