Influence of Microstructural Evolution on the Magnetically Group Dominance in Polycrystalline Y3Fe5O12 Multi-Samples

In present work, the effect of changing microstructure on magnetic properties which evolves in parallel, in particular from amorphous-to-crystalline development, in yttrium iron garnet was investigated. 9 toroidal samples of polycrystalline yttrium iron garnets were prepared by using the mechanical alloying technique and sintered at low to high sintering temperature for microstructure-dependent-magnetic evolutions. A brief, yet revealing characterization of the samples were carried out by using an X-ray Diffraction, Field Emission Scanning Electron Microscopy, Impedance Material Analyzer, LCR-meter and, Picoammeter. It is believed that microstructural features such as amorphous phase, grain boundary, secondary phase and intergranular pores contribute significant additional magnetic anisotropy and demagnetizing fields, thus affecting the initial permeability accordingly. A scrutinizing observation of the permeability component results show that they tend to fall into three groups of magnetic permeability according to degree of magnetic behaviour dominance. The Curie temperature remained relatively stable and unaffected by the evolution, thus confirming its intrinsic character of being dependent only on the crystal structure and compositional stoichiometry. The increased electrical resistivity while the microstructure was evolving is believed to strongly indicate improved phase purity and compositional stoichiometry.

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Effect of substituted concentration on structure and magnetic properties of Y3Fe5-xInxO12

VNU Journal of Science Mathematics - Physics ◽

10.25073/2588-1124/vnumap.4298 ◽

2018 ◽

Vol 34 (4) ◽

Author(s):

Nguyen Phuc Duong ◽

Vu Thi Hoai Huong ◽

Dao Thi Thuy Nguyet

Keyword(s):

Magnetic Properties ◽

Curie Temperature ◽

Magnetic Materials ◽

Single Phase ◽

Sol Gel ◽

Applied Physics ◽

Yttrium Iron ◽

Iron Garnets ◽

Iron Garnet ◽

Yttrium Iron Garnets

Abstract: This study examines the effect of substituted concentration on the structure and magnetic properties of Y3Fe5-xInxO12 (x = 0.1 ÷ 0.7) powder samples prepared using the sol-gel method. The morphological properties of the samples were analysed using XRD, SEM. The single phase of garnet was obtained in x = 0.1 ÷ 0.6 samples. The lattice parameters of the samples exhibit a linear increase with the increasing In3+ content, which can be explained by a substitution of In3+ ions for Fe3+ ions, considering the larger ionic radius of In3+ compared with that of Fe3+. Crystallite sizes were determined via the XRD data which are of 38 – 49 nm while the particle sizes were estimated from SEM images to be in range of 50 - 100 nm. Magnetization and Curie temperature of the single phase samples were studied by magnetization curves in fields up to 10 kOe and in the temperature range from 80 K to 560K. With the increase of In3+, the magnetization gradually increases while the Curie temperature decreases due to the occupation of In atoms at the a sites and the reduction of intersublattice interaction, respectively. Keywords: Yttrium iron garnet, Indium substitution, cation distribution, magnetization, Curie temperature. References[1] R. L. Streever, Anisotropic exchange in ErIG, Journal of Magnetism and Magnetic Materials 278 (1-2) (2014) 223-230.[2] N.I. Tsidaeva, The magnetic and magnetooptical properties of Y-substituted erbium iron garnet single crystals, Journal of Alloys and Compounds 374 (1-2) (2004) 160-164.[3] Y.Nakata, T. Okada, M. Maeda, S. Higuchi and K. Ueda, Effect of oxidation dynamics on the film characteristics of Ce:YIG thin films deposited by pulsed laser deposition, Optics and Lasers in Engineering 44 (2) 2006, 147-154.[4] M. Laulajainen, P. Paturi, J. Raittila, H. Huhtinen, A.B. Abrahamsen, N.H. Andersen and R. Laiho, BixY3-xFe5O12 thin film prepared by laser ablation for magneto-optical imaging of superconducting thin films, Journal of Magnetism and Magnetic Materials 279 (2-3) (2004) 218-223.[5] A.A. Lagutin, G.E. Fedorov, J. Vanacken and D. Herlach, Magnetic properties of dysprosium Yttrium ferrite garnet in pulsed magnetic fields at low temperatures, Journal of Magnetism and Mmagnetic Materials 195 (1999) 97-106.[6] S.A. Nikotov, Nonlinearity: Magneto-optic microwave interactions. Towards new devices, Journal of Magnetism and Magnetic Materials (196-197) (1999) 400-403.[7] C.S. Tsai, Wideband tunable microwave devices using, European Ceramic Society 23 (14) (2003) 2721-2726.[8] A. Sztaniszlav, M. Farkas-Jahnke, M. Balla, Kinetics of garnet formation in In3+ substituted systems, Journal of Magnetism and Magnetic Materials 215-216 (2000) 188-193.[9] R.G. Vidhate, V.D. Murumkas, R.G. Dorik, N.M. Makne, S.R. Nimbore, K.M. Jadhav, Magnetic properties of In Substituted ytrium iron garnet (YIG), Rev. Res. 1(10) (2012) 1-4.[10] G. Cuijing, Z. Wei, J. Rongjin, Z. Yanwei, Effect of In3+ substitution on the structure and magnetic properties of multi-doped YIG ferrites with low saturation magnetizations, Journal of Magnetism and Magnetic Materials 323, (2011) 611-615.[11] Vu Thi Hoai Huong, Dao Thi Thuy Nguyet, To Thanh Loan, Luong Ngoc Anh, Nguyen Phuc Duong, Than Duc Hien, Structural and magnetic properties of Y3-2xCa2xFe5-xVxO12 nanoparticles prepared by sol-gel method, Proceeding of the 3rd International Conference on Advanced Materials and Nanotechnology (2016) 219-223.[12] Imaddin A. Al-Omari, Ralph Skomski, David J. Sellmyer, Magnetic properties of Y3-2xCa2xFe5-xVxO12 garnets, Advances in Materials Physics and Chemistry 2 (2012) 116-120.[13] Rodziah Nazlan, Mansorhashim, Idza Riati Ibrahim, Fadzidah Mohd Idris, Wan Norailiana Wan Ab Rahman, Nor Hapishah Abdullah, Ismayadi Ismail, Saikannu Kanagesan, Zulkifly Abbas, Rabaah Syahidah Azis, Influence of Indium substitution and microstructure changes on the magnetic properties evolution of Y3Fe5-xInxO12 (x = 0.0 – 0.4), Journal of Material Science: Materials in Electronics 26, 6 (2015) 3596-3609.[14] M. Niyaifar, A. Beitollahi, N. Shiri, M. Mozaffari, J. Amighian, Effect of indium addition on the structure and magnetic properties of YIG, Journal of Magnetism and Magnetic Materials 322 (2010) 777 – 779.[15] J. Richard Cunningham Jr and Elmer E. Anderson, Effect of indium substitution in Yttrium iron garnet. High permeability garnets, Journal of Applied Physics 32, (1961) S388.[16] L. Vegard Dr. Phil, LV. Results of crystal analysis. –III, Philosophical magazine Series 6, 32: 191, 505 – 518.[17] Ronald W. Armstrong, Crystal dislocations, Crystals 6, 1 (2016) 9.[18] Gerald F. Dionne, Molecular field coefficients of substituted yttrium iron garnets, Journal of Applied Physics. 41 (1970) 4874.[19] M.A. Gilleo, Ferromagnetic insulators: Garnets, in: E.P. Wohlfarth (Ed.), Handbook of Magnetic Materials, Volume 2, North-Holland Publishing Company, 1980, 1-54.[20] Z. Azadi Motlagh, M. Mozaffari, J. Smighian, Preparation of nano-sized Al-substituted yttrium iron garnets by the mechanochemical method and investigation of their magnetic properties, Journal of Magnetism and Magnetic Materials 321 (2009) 1980-1984.[21] P. Belov and I.S. Lyubutin, Effective magnetic fields at tin nuclei in substituted iron garnets CaxY3-x SnxFe5-x O12, Soviet Physics JETP 22 (3) (1966) 518 – 520.

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Initial Permeability and Derived Anisotropy of Scandium‐Substituted Yttrium Iron Garnets

Journal of Applied Physics ◽

10.1063/1.1714518 ◽

1965 ◽

Vol 36 (8) ◽

pp. 2491-2496 ◽

Cited By ~ 18

Author(s):

J. Richard Cunningham

Keyword(s):

Initial Permeability ◽

Yttrium Iron ◽

Iron Garnets ◽

Yttrium Iron Garnets

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Stress Dependence of Photoinduced Magnetostriction in Yttrium Iron Garnets

Solid State Phenomena ◽

10.4028/www.scientific.net/ssp.215.314 ◽

2014 ◽

Vol 215 ◽

pp. 314-319 ◽

Cited By ~ 1

Author(s):

Natalya V. Vorob'eva

Keyword(s):

Single Crystals ◽

Yttrium Iron Garnet ◽

Internal Stresses ◽

Stress Dependence ◽

Response Type ◽

Yttrium Iron ◽

Iron Garnets ◽

Iron Garnet ◽

Photoinduced Changes ◽

Yttrium Iron Garnets

The present study investigates photoinduced changes of magnetostriction in yttrium-iron garnet (YIG) single crystals. Single crystals of Y3Fe5O12 were grown from BaO-B2O3 (YIG(Ba)), PbO-PbF2 (YIG(Pb)) and PbO-PbF2:SiO2 (YIG(Si)) solutions from flux. Photoinduced magnetostrictive response types for these three kinds of YIG crystals are quite different. The magnetostrictive constants, the trigonal symmetric internal stresses and their photoinduced changes were calculated for all samples. The conclusion is that the internal stresses in the crystal lattice, caused by defects, determine the photoinduced response type of the crystal.

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Dependence of 57Fe Hyperfine Field in Yttrium Iron Garnet on Ionic Radius of Diamagnetic Defects: NMR Study

Australian Journal of Physics ◽

10.1071/p97051 ◽

1998 ◽

Vol 51 (2) ◽

pp. 437 ◽

Cited By ~ 8

Author(s):

H. Štepánková ◽

J. Kohout ◽

P. Novák ◽

J. Englich ◽

E.-G. Caspary ◽

...

Keyword(s):

Hyperfine Field ◽

Yttrium Iron Garnet ◽

Nmr Spectra ◽

Ionic Radius ◽

Tolerance Interval ◽

Yttrium Iron ◽

Iron Garnets ◽

Nmr Study ◽

Iron Garnet ◽

Yttrium Iron Garnets

Satellite structure in 57Fe NMR spectra of In3+ , Sc3+ , Ga3+ and Al3+ substituted yttrium iron garnets (YIG) was analysed taking into account results previously obtained for ‘antisit’ defects (Y3+ ions on Fe3+ sites) in nominally pure YIG. The influences of the diamagnetic substitution on the hyperfine field at the neighbouring iron nuclei were found to be remarkably dependent on the ionic radius of the substituent. In the case of two substituents in the vicinity of the resonating iron, an additivity of their effects within a 15% tolerance interval was verified.

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