Research output: Contribution to journal › Article › peer-review
Influence of the Preparation Technique on the Magnetic Characteristics of ε-Fe2O3-Based Composites. / Testov, Dmitriy O.; Gareev, Kamil G.; Khmelnitskiy, Ivan K.; Kosterov, Andrei; Surovitskii, Leonid; Luchinin, Victor V.
In: Magnetochemistry, Vol. 9, No. 1, 10, 2023.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Influence of the Preparation Technique on the Magnetic Characteristics of ε-Fe2O3-Based Composites
AU - Testov, Dmitriy O.
AU - Gareev, Kamil G.
AU - Khmelnitskiy, Ivan K.
AU - Kosterov, Andrei
AU - Surovitskii, Leonid
AU - Luchinin, Victor V.
N1 - Testov, D.O.; Gareev, K.G.; Khmelnitskiy, I.K.; Kosterov, A.; Surovitskii, L.; Luchinin, V.V. Influence of the Preparation Technique on the Magnetic Characteristics of ε-Fe2O3-Based Composites. Magnetochemistry 2023, 9, 10. https://doi.org/10.3390/magnetochemistry9010010
PY - 2023
Y1 - 2023
N2 - ε-Fe2O3 is an iron(III) oxide polymorph attracting an increasing interest due to its unique magnetic properties combining extremely high coercivity and relatively large saturation magnetization. We review existing methods for the ε-Fe2O3 synthesis focusing on synthesis speed, repeatability, manufacturability and purity of the final product. Samples of ε-Fe2O3 have been synthesized using the two methods that appear the most promising: silica gel impregnation and microemulsion. In both cases, ε-Fe2O3 and α-Fe2O3 are present in the final product as attested by X-ray diffraction patterns and magnetic properties (maximum coercive force at 300 K~1 Tesla). Two different precursors, iron(III) nitrate and iron(II) sulfate, have been used in the silica gel impregnation method. Somewhat surprisingly, iron sulfate proved superior yielding ε-Fe2O3 content of 69% in the total iron oxide product, compared to 25% for iron nitrate under the same synthesis conditions. These results pave the way for modifying the existing ε-Fe2O3 synthesis methods aiming to increase the content of the epsilon phase in the final product and, consequently, improve its physicochemical properties.
AB - ε-Fe2O3 is an iron(III) oxide polymorph attracting an increasing interest due to its unique magnetic properties combining extremely high coercivity and relatively large saturation magnetization. We review existing methods for the ε-Fe2O3 synthesis focusing on synthesis speed, repeatability, manufacturability and purity of the final product. Samples of ε-Fe2O3 have been synthesized using the two methods that appear the most promising: silica gel impregnation and microemulsion. In both cases, ε-Fe2O3 and α-Fe2O3 are present in the final product as attested by X-ray diffraction patterns and magnetic properties (maximum coercive force at 300 K~1 Tesla). Two different precursors, iron(III) nitrate and iron(II) sulfate, have been used in the silica gel impregnation method. Somewhat surprisingly, iron sulfate proved superior yielding ε-Fe2O3 content of 69% in the total iron oxide product, compared to 25% for iron nitrate under the same synthesis conditions. These results pave the way for modifying the existing ε-Fe2O3 synthesis methods aiming to increase the content of the epsilon phase in the final product and, consequently, improve its physicochemical properties.
KW - iron(III) oxide
KW - polymorphism
KW - synthesis
KW - magnetic materials
KW - high coercive force
UR - https://www.mendeley.com/catalogue/c1b52560-711c-3a4c-9c60-3853b4e81638/
U2 - 10.3390/magnetochemistry9010010
DO - 10.3390/magnetochemistry9010010
M3 - Article
VL - 9
JO - Magnetochemistry
JF - Magnetochemistry
SN - 2312-7481
IS - 1
M1 - 10
ER -
ID: 102798532