References
- Varga LK. Soft magnetic nanocomposites for high-frequency and high-temperature applications. J Magn Magn Mater. 2007;316:442–447.
- Karimou M, Yessoufou RA, Guedje FK, et al. Magnetic behavior of a mixed spin-1 and spin-7 2 Blume–Capel model on the Bethe lattice in the presence of an applied magnetic field. Phase Transit. 2016. doi:10.1080/01411594.2016.1179739
- Sullivan CR, Prabhakaran S, Dhagat P, et al. Thin-film inductor designs and materials for high-current low-voltage power. Trans Magn Soc Jpn. 2003;3:126–128.
- Shimada Y, Yamaguchi M, Ohnuma S, et al. Granular thin films with high RF permeability. IEEE Trans Magn. 2003;39:3052–3056.
- Sarac U, Baykul MC, Uguz Y. The influence of applied current density on microstructural, magnetic, and morphological properties of electrodeposited nanocrystalline Ni–Co thin films. J Supercond Novel Magn. 2015;28:1041–1045.
- Hemeda OM, Tawfik A, El-Sayed AH, et al. Synthesis and characterization of semi-crystalline NiCoP film. J Supercond Novel Magn. 2015;28:3629–3632.
- Karpuz A, Kockar H, Alper M. Electrodeposited Co–Ni films: electrolyte pH–property relationships. J Supercond Novel Magn. 2013;26:651–655.
- El-Sayed AH, Hemeda OM, Tawfik A, et al. Greatly enhanced magnetic properties of electrodeposited Ni–Co–P-BaFe12O19 composites. J Magn Magn Mater. 2016;402:105–109.
- Hamad MA, El-Sayed AH, Hemeda OM, et al. Strong coercivity reduction and high initial permeability in NiCoP coated BaFe12O19–polystyrene bilayer composite. Mater Res Exp. 2016;3:036104.
- Pané S, Gómez E, García-Amorós J, et al. First stages of barium ferrite microparticles entrapment in the electrodeposition of CoNi films. J Electroanal Chem. 2007;604:41–47.
- Pané S, Gómez E, Vallés E. Enhanced magnetism in electrodeposited-based CoNi composites containing high percentage of micron hard-magnetic particles. Electrochem Commun. 2007;9:1755–1760.
- Cojocaru P, Magagnin L, Gomez E, et al. Nanowires of NiCo/barium ferrite magnetic composite by electrodeposition. Mater Lett. 2011;65:2765–2768.
- El-Sayed AH, Hemeda OM, Tawfik A, et al. Simulation of wasp-waisted magnetic hysteresis loop for NiCoP coated BaFe12O19–polystyrene bilayer composite film. J Supercond Novel Magn. 2016. doi:10.1007/s10948-016-3562-7
- Guan S, Nelson BJ, Vollmers K. Electrochemical codeposition of magnetic particle–ferromagnetic matrix composites for magnetic MEMS actuator applications. J Electrochem Soc. 2004;151:C545–C549.
- Lakshman A, Rao KH, Mendiratta RG. Magnetic properties of In3+ and Cr3+ substituted Mg–Mn ferrites. J Magn Magn Mater. 2002;250:92–97.
- Tawfik A, Hemeda OM, El-Sayed AH, et al. Initial magnetic permeability of M type BaFe12O19–polystyrene composite. J Supercond Novel Magn. 2016. doi:10.1007/s10948-016-3518-y
- El-Sayed AH, Hemeda OM, Tawfik A, et al. Remarkable magnetic enhancement of type-M hexaferrite of barium in polystyrene polymer. AIP Adv. 2015;5:107131.
- Pereira FM, Junior CA, Santos MR, et al. Structural and dielectric spectroscopy studies of the M-type barium strontium hexaferrite alloys (BaxSr1−xFe12O19). J Mater Sci Mater Electron. 2008;19:627–638.
- Elkady HA, Abou‐Sekkina MM, Nagorny K. New information on Mössbauer and phase transition properties of Z-type hexaferrites. Hyperf Inter. 2000;128:423–432.
- Shi X, Pu Y, Liu D. Preparation of magnetic barium ferrite powders by microwave hydrothermal method. J Ceram Process Res. 2012;13:414–417.
- Huang J, Zhuang H, Li W. Synthesis and characterization of nano crystalline BaFe 12 O 19 powders by low temperature combustion. Mater Res Bull. 2003;38:149–159.
- Lallart M. Ferroelectrics: characterization and modeling. New York (NY): InTech; 2011.
- Grelfer AP, Nakada Y, Lessofe H. Preparation and properties of low-loss ferrites. J Appl Phys. 1961;32:S382–S383.
- Herzer G. Nanocrystalline soft magnetic alloys. Handbook of magnetic materials. Vol. 10. Amsterdam: Elsevier; 1997. p. 415–462.
- Shen W. Design of high-density transformers for high-frequency high-power converters [Doctoral dissertation]. Virginia Polytechnic Institute and State University; 2006.
- Yang C, Liu F, Ren T, et al. Fully integrated ferrite-based inductors for RF ICs. Sens Actuators A. 2006;130:365–370.
- Hamad MA. Magnetocaloric effect in (001)-oriented MnAs thin film. J Supercond Novel Magn. 2014;27:263–267.
- Hamad MA. Simulation of magnetocaloric effect in La0.7Ca0.3MnO3 ceramics fabricated by fast sintering process. J Supercond Novel Magn. 2014;27:269–272.
- Hamad MA. Magnetocaloric effect in La1.25Sr0.75MnCoO6. J. Therm. Anal. Calorim. 2014:115:523–526.
- Hamad MA. Magnetocaloric effect of perovskite Eu0.5Sr0.5CoO3. J Supercond Novel Magn. 2014;27:277–280.
- Hamad MA. Magnetocaloric effect in La0.7Sr0.3MnO3/Ta2O5 composites. J. Adv. Ceram. 2013;2:213–217.
- Hamad MA. Magnetocaloric Effect in Half-Metallic Double Perovskite Sr0.4Ba1.6−xSrxFeMoO6. Int. J. Thermophys. 2013;34:2144–2151.
- Hamad MA. Simulation of Magnetocaloric Properties of Antiperovskite Structural Ga1−XAlXCMn3. J Supercond Novel Magn. 2014;27:2569–2572.
- Hamad MA. Magnetocaloric Effect in Sr0.4Ba1.6−xLaxFeMoO6. J Supercond Novel Magn. 2014;27:1777–1780.