Study of the Structural and Magnetic Properties of Co-Substituted Ba2Mg2Fe12O22 Hexaferrites Synthesized by Sonochemical Co-Precipitation

Koutzarova, T.; Kolev, Svetoslav; Krezhov, K.; Georgieva, Borislava; Kovacheva, Daniela; Ghelev, Chavdar; Vertruyen, Bénédicte; Boschini, Frèdéric; Mahmoud, Abdelfattah; Tran, Lan Maria; Zaleski, A.

doi:10.3390/ma12091414

Cited by 11 publications

(10 citation statements)

References 41 publications

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“…The synthesis of Y-type hexaferrites is commonly accompanied by the formation of different oxides, usually spinels, mainly because the temperature range for synthesising the Y-phase is rather narrow. However, in what concerns the magnetic phase transitions, our previous studies [9,12,13] on other Y-hexaferrite compositions have shown that the trace amount of spinel ferrites in the material studied does not affect the magnetic-phase transition temperatures. In figure 2, we display the initial magnetisation and the hysteresis curves of the Ba0.5Sr1.5NiMgFe12O22 powder at 300 K and 4.2 K. As seen, the magnetisation curves for both temperatures do not reach saturation at the highest magnetic field used of 50 kOe, the highest magnetisation values being 32 emu/g and 24 emu/g respectively at 4.2 K and 300 K. The magnetisation values determined are typical for Y-type hexaferrites.…”

Section: Resultsmentioning

confidence: 86%

Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions

Georgieva

Kolev

Ghelev

et al. 2022

J. Phys.: Conf. Ser.

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We investigated the magnetic properties and magnetic phase transition in Y-type Ba0.5Sr1.5NiMgFe12O22 hexaferrite powder prepared by citrate sol-gel spontaneous combustion. The saturation magnetisation value of 32 emu/g at 4.2 K was lowered to 24 emu/g at 300 K. The magnetisations curves did not saturate even at a magnetic field of 50 kOe for both temperatures - 4.2 K and 300 K. A step-like behaviour appeared in the initial magnetisation curve at 4.2 K. A magnetic phase transformation from a spiral magnetic ordering to a conical spin one was observed at 40 K.

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Section: Resultsmentioning

confidence: 86%

Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions

Georgieva

Kolev

Ghelev

et al. 2022

J. Phys.: Conf. Ser.

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“…ZFC and FC magnetization as a function of the temperature for Ba 2 Mg 0.4 Co 1.6 Fe 12 O 22 in a magnetic field of (a) 50 Oe, (b) 100 Oe, (c) 500 Oe, and (d) 1 kOe. Reprinted with permission from ref . Copyright 2019 MDPI.…”

Section: Magnetic Phase Transitionsmentioning

confidence: 76%

“…Rhee et al 27 investigated the ZFC magnetization changes for Ba 2 Co 2 Fe 12 O 22 in a magnetic field of 100 Oe; they observed the magnetic phase transition from a helimagnetic spin ordering to a ferromagnetic one to take place at 215 K and determined the T N to be 615 K. The Neél temperature is higher than that for Ba 2 Mg 2 Fe 12 O 22 and Ba 2 Zn 2 Fe 12 O 22 due to the presence of the magnetic Co 2+ cation leading to stronger superexchange interactions Co 2+ − O 2− −Fe 3+ (Co 2+ ). Lim et al 53 studied the ZFC magnetization of Ba 2 Mg 0.5 Co 1.5 Fe 12 O 22 in the 50−740 K temperature interval and a magnetic field of 100 Oe and detected a magnetic phase transition from a helimagnetic spin ordering to a ferromagnetic one at 206 K. Our studies 42 on the influence of the partial substitution of nonmagnetic Mg 2+ cations with magnetic Co 2+ cations in Ba 2 Mg 0.4 Co 1.6 Fe 12 O 22 showed that the phase transition temperature is rather sensitive to the applied magnetic field strength, namely, it decreases from 225 K (at 50 Oe) to 135 K (at 1 kOe). We also observed a different behavior of the ZFC curves for magnetic field strengths exceeding 500 Oe.…”

Section: ■ Magnetic Phase Transitionsmentioning

confidence: 99%

“…Lim et al . studied the ZFC magnetization of Ba 2 Mg 0.5 Co 1.5 Fe 12 O 22 in the 50–740 K temperature interval and a magnetic field of 100 Oe and detected a magnetic phase transition from a helimagnetic spin ordering to a ferromagnetic one at 206 K. Our studies on the influence of the partial substitution of nonmagnetic Mg 2+ cations with magnetic Co 2+ cations in Ba 2 Mg 0.4 Co 1.6 Fe 12 O 22 showed that the phase transition temperature is rather sensitive to the applied magnetic field strength, namely, it decreases from 225 K (at 50 Oe) to 135 K (at 1 kOe). We also observed a different behavior of the ZFC curves for magnetic field strengths exceeding 500 Oe.…”

Section: Magnetic Phase Transitionsmentioning

confidence: 99%

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Phase Transitions in Magneto-Electric Hexaferrites

et al. 2022

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Hexaferrites have long been the object of extensive studies because of their great possibility for applications�permanent magnets, highdensity recording media, microwave devices, in biomedicine, to name but a few. Lately, many researchers' efforts have been focused on the existence of the magneto-electric effect in some hexaferrite systems and the appealing possibility of them being used as single-phase multiferroic and magnetoelectric materials. As indicated by theoretical analyses, the origin of the large magneto-electric effect can be sought in the strong interaction between the magnetization and the electric polarization that coexist in insulators with noncollinear magnetic structures. The hexaferrites' magnetic structure and, particularly, the specific magnetic spin ordering are the key factors in observing magneto-electric phases in hexaferrites. Some of these phases are metastable, which hampers their direct practical use. However, as the hexaferrites' phase diagrams reveal, chemical doping can be used to prepare a number of noncollinear stable magnetic phases. Since the magneto-electric effect has to do with the magnetic moments ordering, it seems only logical that one should study the cation substitutions' influence on the magnetic phase transition temperature. In this paper, we summarize recent examples of advances in the exploration of magnetic phase transitions in Y-type hexaferrites. In particular, the effect is emphasized by substituting in Y-type hexaferrites the nonmagnetic Me 2+ cations with magnetic ones and of the magnetic Fe 3+ cations with nonmagnetic ones on their magnetic properties and magnetic phase transitions. The work deals with the structural properties of and the magnetic phase transitions in a specific Y-type hexaferrite, namely, Ba(Sr) 2 Me 2 Fe 12 O 22 .

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“…Using various divalent cations (Ba, Sr, and Co) and tuning the stoichiometry, hexagonal ferrites of several sorts (M, Y, Z, W, X, and U) can be produced [ 1 , 7 ]. Magnetoelectric (ME)/multiferroic phenomena are one of the most exciting discoveries of hexagonal ferrites [ 7 , 8 , 9 ]. Previous studies have revealed that magnetically induced ferroelectricity can be manifested by complex internal arrangements of magnetic moments in hexagonal ferrites, in which ferromagnetic properties are intrinsically coupled to their atomic structures [ 1 , 7 , 8 , 10 , 11 , 12 , 13 , 14 ].…”

Section: Introductionmentioning

confidence: 99%

Real-Time Observation of Magnetic Domain Structure Changes with Increasing Temperature for Z-Type Hexagonal Ferrite

Kim

Park

2022

Materials

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Z-type hexagonal ferrites have recently received attention for their room-temperature magnetoelectric (ME), which is activated when the temperature at which the transverse-conical spin-state transitions to a ferrimagnetic state is increased. The changes in the magnetic domain structure at the transition have been well-documented; however, they are still not understood in detail. In the present study, Lorentz transmission electron microscopy (TEM) analysis combined with an in situ heating experiment was conducted to demonstrate the shift in magnetic domain structure during the transition from the transverse-conical spin arrangement to a ferrimagnetic spin order. The dynamics of the magnetic domain structure changes with the increasing temperature were acquired in real-time. At 490 K, the magnetization transition from the transverse-conical spin state to the ferromagnetic state was demonstrated. Cross-tie domain walls formed during the magnetic transition process. The increased effect of the demagnetizing field applied to the 180° magnetic domains was caused by a lower magnetocrystalline anisotropy (MCA) at the easy axis of magnetization.

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Study of the Structural and Magnetic Properties of Co-Substituted Ba2Mg2Fe12O22 Hexaferrites Synthesized by Sonochemical Co-Precipitation

Cited by 11 publications

References 41 publications

Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions

Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions

Phase Transitions in Magneto-Electric Hexaferrites

Real-Time Observation of Magnetic Domain Structure Changes with Increasing Temperature for Z-Type Hexagonal Ferrite

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Study of the Structural and Magnetic Properties of Co-Substituted Ba2Mg2Fe12O22 Hexaferrites Synthesized by Sonochemical Co-Precipitation

Cited by 11 publications

References 41 publications

Effect of cation substitutions in Y-type Ba0.5Sr1.5Me2Fe12O22 hexaferrites on the magnetic phase transitions

Effect of cation substitutions in Y-type Ba0.5Sr1.5Me2Fe12O22 hexaferrites on the magnetic phase transitions

Phase Transitions in Magneto-Electric Hexaferrites

Real-Time Observation of Magnetic Domain Structure Changes with Increasing Temperature for Z-Type Hexagonal Ferrite

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Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions

Effect of cation substitutions in Y-type Ba_0.5Sr_1.5Me₂Fe₁₂O₂₂ hexaferrites on the magnetic phase transitions