New insights into the electrochemical formation of magnetite nanoparticles
New insights into the electrochemical formation of magnetite nanoparticles
The electrochemical mechanism of the formation of magnetite nanoparticles is studied. The proposed mechanism suggests the formation of iron hydroxide Fe(OH)2 in the presence of oxygen which produces lepidocrocite (γ-FeOOH) followed by its chemical dehydration. This is in contrast to other reported mechanisms that suggest the reduction of Fe(OH)3 at the cathode. Video frames captured during the electrosynthesis of magnetite, in a typical two-electrode cell, indicate that the nanoparticles form in the region close to the anode. The pH value near the anode and cathode changes with time, indicating the formation of nanoparticles. Additional experiments in a two-compartment cell fitted with a cationic membrane, to avoid direct intermixing of Fe2+ and OH− and possible oxide or oxyhydroxide reduction at the cathode, support this mechanism. The amount of dissolved oxygen in the electrolyte was found to be a key factor to produce magnetite by promoting the transformation of Fe(OH)2 into (γ-FeOOH). Hydrogen bubbling during electrosynthesis does not contribute to the reduction of the oxyhydroxides, according to X-ray diffraction results. The paper presents a proposed mechanism for the formation of magnetite, based on previous and new evidence.
electrochemical mechanism; electrosynthesis; lepidocrocite; magnetite; nanoparticles
D184-D191
Lozano, I.
62e061e3-7ba6-4e17-aadf-47ab566fd984
Casillas, N.
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Ponce De Leon Albarran, C.
508a312e-75ff-4bcb-9151-dacc424d755c
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2
Herrasti, P.
9ec58bb1-128c-4204-853f-804a91926275
Lozano, I.
62e061e3-7ba6-4e17-aadf-47ab566fd984
Casillas, N.
39ced5c0-db14-4439-9615-07627a385252
Ponce De Leon Albarran, C.
508a312e-75ff-4bcb-9151-dacc424d755c
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2
Herrasti, P.
9ec58bb1-128c-4204-853f-804a91926275
Lozano, I., Casillas, N., Ponce De Leon Albarran, C., Walsh, F.C. and Herrasti, P.
(2017)
New insights into the electrochemical formation of magnetite nanoparticles.
Journal of the Electrochemical Society, 164 (4), .
(doi:10.1149/2.1091704jes).
Abstract
The electrochemical mechanism of the formation of magnetite nanoparticles is studied. The proposed mechanism suggests the formation of iron hydroxide Fe(OH)2 in the presence of oxygen which produces lepidocrocite (γ-FeOOH) followed by its chemical dehydration. This is in contrast to other reported mechanisms that suggest the reduction of Fe(OH)3 at the cathode. Video frames captured during the electrosynthesis of magnetite, in a typical two-electrode cell, indicate that the nanoparticles form in the region close to the anode. The pH value near the anode and cathode changes with time, indicating the formation of nanoparticles. Additional experiments in a two-compartment cell fitted with a cationic membrane, to avoid direct intermixing of Fe2+ and OH− and possible oxide or oxyhydroxide reduction at the cathode, support this mechanism. The amount of dissolved oxygen in the electrolyte was found to be a key factor to produce magnetite by promoting the transformation of Fe(OH)2 into (γ-FeOOH). Hydrogen bubbling during electrosynthesis does not contribute to the reduction of the oxyhydroxides, according to X-ray diffraction results. The paper presents a proposed mechanism for the formation of magnetite, based on previous and new evidence.
Text
New insights into the electrochemical formation of magnetite nanoparticles
- Accepted Manuscript
More information
Accepted/In Press date: 14 February 2017
e-pub ahead of print date: 14 February 2017
Keywords:
electrochemical mechanism; electrosynthesis; lepidocrocite; magnetite; nanoparticles
Organisations:
Energy Technology Group
Identifiers
Local EPrints ID: 406220
URI: http://eprints.soton.ac.uk/id/eprint/406220
ISSN: 0013-4651
PURE UUID: 40afbb05-3b30-4339-80a1-3165afe0c272
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Date deposited: 10 Mar 2017 10:42
Last modified: 16 Mar 2024 03:43
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Author:
I. Lozano
Author:
N. Casillas
Author:
P. Herrasti
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