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Exploring the oxidation behavior of undiluted and diluted iron particles for energy storage: Mössbauer spectroscopic analysis and kinetic modeling

Spielmann, Jonas ; Braig, Daniel ; Streck, Antonia ; Gustmann, Tobias ; Kuhn, Carola ; Reinauer, Felix ; Kurnosov, Alexandr ; Leubner, Oliver ; Potapkin, Vasily ; Hasse, Christian ; Deutschmann, Olaf ; Etzold, Bastian J. M. ; Scholtissek, Arne ; Kramm, Ulrike I. (2024)
Exploring the oxidation behavior of undiluted and diluted iron particles for energy storage: Mössbauer spectroscopic analysis and kinetic modeling.
In: Physical Chemistry Chemical Physics, 2024, 26 (17)
doi: 10.26083/tuprints-00027310
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Item Type: Article
Type of entry: Secondary publication
Title: Exploring the oxidation behavior of undiluted and diluted iron particles for energy storage: Mössbauer spectroscopic analysis and kinetic modeling
Language: English
Date: 13 May 2024
Place of Publication: Darmstadt
Year of primary publication: 10 April 2024
Place of primary publication: Cambridge
Publisher: Royal Society of Chemistry
Journal or Publication Title: Physical Chemistry Chemical Physics
Volume of the journal: 26
Issue Number: 17
DOI: 10.26083/tuprints-00027310
Corresponding Links:
Origin: Secondary publication DeepGreen
Abstract:

Iron is an abundant and non-toxic element that holds great potential as energy carrier for large-scale and long-term energy storage. While from a general viewpoint iron oxidation is well-known, the detailed kinetics of oxidation for micrometer sized particles are missing, but required to enable large-scale utilization for energy production. In this work, iron particles are subjected to temperature-programmed oxidation. By dilution with boron nitride a sintering of the particles is prevented enabling to follow single particle effects. The mass fractions of iron and its oxides are determined for different oxidation times using Mössbauer spectroscopy. On the basis of the extracted phase compositions obtained at different times and temperatures (600–700 °C), it can be concluded that also for particles the oxidation follows a parabolic rate law. The parabolic rate constants are determined in this transition region. Knowledge of the particle size distribution and its consideration in modeling the oxidation kinetics of iron powder has proven to be crucial.

Status: Publisher's Version
URN: urn:nbn:de:tuda-tuprints-273103
Classification DDC: 500 Science and mathematics > 540 Chemistry
600 Technology, medicine, applied sciences > 620 Engineering and machine engineering
Divisions: 16 Department of Mechanical Engineering > Simulation of reactive Thermo-Fluid Systems (STFS)
07 Department of Chemistry > Eduard Zintl-Institut
DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1487: Iron, upgraded!
Date Deposited: 13 May 2024 13:21
Last Modified: 12 Sep 2024 09:18
SWORD Depositor: Deep Green
URI: https://tuprints.ulb.tu-darmstadt.de/id/eprint/27310
PPN: 521333261
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