Magnetic Properties of Manganese-Zinc Soft Ferrite Ceramic for High Frequency Applications

Petrescu, Lucian; Petrescu, Maria-Cătălina; Ioniţă, Valentin; Cazacu, Emil; Constantinescu, Catalin-Daniel

doi:10.3390/ma12193173

Cited by 25 publications

(11 citation statements)

References 30 publications

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“…Bahiraei and Hangi 17 reviewed the MNFs in numerous thermal applications such as thermomagnetic convection, heat pipes, and coolant in the thermal management system. Petrescu et al 18 highlight the magnetic properties of Mn–ZnFe 2 O 4 (soft ferrite) for high‐frequency transformer cores and planar induct applications. Experimental works pertaining to ferrofluids were conducted by Ghofrani et al, 19 Yang et al, 20 and Patel et al 21 …”

Section: Introductionmentioning

confidence: 99%

“…15,16 Bahiraei and Hangi 17 reviewed the MNFs in numerous thermal applications such as thermomagnetic convection, heat pipes, and coolant in the thermal management system. Petrescu et al 18 highlight the magnetic properties of Mn-ZnFe 2 O 4 (soft ferrite) for high-frequency transformer cores and planar induct applications. Experimental works pertaining to ferrofluids were conducted by Ghofrani et al, 19 Yang et al, 20 and Patel et al 21 The investigation of heat transfer and boundary layer flow shows an upturn trend and perennial demands for its contribution in manufacturing processes like hot rolling of continuous filaments, glass-fiber production, polymer extrusion, and crystal growing.…”

Section: Introductionmentioning

confidence: 99%

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Insight into three‐dimensional flow of three different dynamics of nanofluids subject to thermal radiation: The case of water–cobalt ferrite, water–manganese–zinc ferrite, and water–magnetite

et al. 2022

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Magnetic nanofluids (MNFs) have been widely applied in both biomedical and environmental sectors along with the substantial growth of numerical and experimental studies. Hence, in view of the unique properties in MNFs, the aim of this study is to analyze numerically the three-dimensional flow of MNFs (Fe 3 O 4 -water, CoFe 2 O 4 -water, Mn-ZnFe 2 O 4 -water) over a shrinking surface with suction and thermal radiation effects. The single-phase nanofluid model is reduced into a system of ordinary differential equations by applying the similarity transformation. The results are then, obtained using the bvp4c solver in the Matlab software. The results reveal that for the shrinking case, the Mn-ZnFe 2 O 4 -water nanofluid has the maximum thermal rate followed by CoFe 2 O 4 -water and Fe 3 O 4 -water, respectively. Meanwhile, Fe 3 O 4 -water expands the separation value of boundary layer flow greater than other tested MNFs.Besides this, the suction parameter is also a contributing factor for the thermal enhancement of all MNFs.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Insight into three‐dimensional flow of three different dynamics of nanofluids subject to thermal radiation: The case of water–cobalt ferrite, water–manganese–zinc ferrite, and water–magnetite

et al. 2022

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“…It was discovered that the magnetic noise was mostly caused by the complex permeability and conductivity of the material. The conductivity of MnZn ferrite material was ~10 −6 S/m less than that of mu-metal material [ 17 , 18 ]. Through theoretical calculation and experimental research, the noise of the ferrite shield has been reduced by 25 times to 0.75 fT/Hz 1/2 compared with the noise of the mu-metal shield, which is above 40 Hz.…”

Section: Introductionmentioning

confidence: 99%

A High-Performance Magnetic Shield with MnZn Ferrite and Mu-Metal Film Combination for Atomic Sensors

Fang

Sun

et al. 2022

Materials

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This study proposes a high-performance magnetic shielding structure composed of MnZn ferrite and mu-metal film. The use of the mu-metal film with a high magnetic permeability restrains the decrease in the magnetic shielding coefficient caused by the magnetic leakage between the gap of magnetic annuli. The 0.1–0.5 mm thickness of mu-metal film prevents the increase of magnetic noise of composite structure. The finite element simulation results show that the magnetic shielding coefficient and magnetic noise are almost unchanged with the increase in the gap width. Compared with conventional ferrite magnetic shields with multiple annuli structures under the gap width of 0.5 mm, the radial shielding coefficient increases by 13.2%, and the magnetic noise decreases by 21%. The axial shielding coefficient increases by 22.3 times. Experiments verify the simulation results of the shielding coefficient of the combined magnetic shield. The shielding coefficient of the combined magnetic shield is 16.5%. It is 91.3% higher than the conventional ferrite magnetic shield. The main difference is observed between the actual and simulated relative permeability of mu-metal films. The combined magnetic shielding proposed in this study is of great significance to further promote the performance of atomic sensors sensitive to magnetic field.

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“…MnZn ferrite is an important member of the soft magnetic materials, which has been widely used in network communication, information storage, automatic control, medical diagnosis, and various apparatuses from household appliances to scientific equipment [1][2][3]. Moreover, it has superior characteristics such as high magnetic permeability, high electrical resistivity, high stability, large magnetic induction, and low magnetic loss [4][5][6]. Thus, it is crucial to develop MnZn ferrite exhibiting better performances with the rapid development of modern science and technology.…”

Section: Introductionmentioning

confidence: 99%

Influence of MnZn Ferrite Homogeneous Fibers on the Microstructure, Magnetic, and Mechanical Properties of MnZn Ferrite Materials

2022

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MnZn ferrite homogeneous fibers were synthesized via a simple solvothermal method and they were used as a reinforcing phase to prepare homogeneous-fiber-reinforced MnZn ferrite materials. The effects of MnZn ferrite homogeneous fibers (0 wt% to 4 wt%) doping on the microstructure, magnetic, and mechanical properties of MnZn ferrite materials were studied systematically. The results showed that MnZn ferrite homogeneous fibers exhibited high purity, good crystallinity, and smooth 1D fibrous structures, which were homogeneous with MnZn ferrite materials. Simultaneously, a certain content of MnZn ferrite homogeneous fibers helped MnZn ferrite materials exhibit more uniform and compact crystal structures, less porosity, and fewer grain boundaries. In addition, the homogeneous-fiber-reinforced MnZn ferrite materials possessed superior magnetic and mechanical properties such as higher effective permeability, lower magnetic loss, and higher Vickers hardness compared to ordinary MnZn ferrite materials. In addition, the magnetic and mechanical properties of homogeneous-fiber-reinforced MnZn ferrite materials first increased and then gradually decreased as the homogeneous fiber content increased from 0 wt% to 4 wt%. The best magnetic and mechanical properties of materials were obtained as the fiber content was about 2 wt%.

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Magnetic Properties of Manganese-Zinc Soft Ferrite Ceramic for High Frequency Applications

Cited by 25 publications

References 30 publications

Insight into three‐dimensional flow of three different dynamics of nanofluids subject to thermal radiation: The case of water–cobalt ferrite, water–manganese–zinc ferrite, and water–magnetite

Insight into three‐dimensional flow of three different dynamics of nanofluids subject to thermal radiation: The case of water–cobalt ferrite, water–manganese–zinc ferrite, and water–magnetite

A High-Performance Magnetic Shield with MnZn Ferrite and Mu-Metal Film Combination for Atomic Sensors

Influence of MnZn Ferrite Homogeneous Fibers on the Microstructure, Magnetic, and Mechanical Properties of MnZn Ferrite Materials

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