A Review study of Mn-Zn Ferrite with Applications and Synthesis processes

Year : 2024 | Volume : 13 | Issue : 02 | Page : 15-26
    By

    pooja rani,

  • rohitash Kumar,

  1. Research Scholar, Department of Physics, NIILM University, Kaithal, India
  2. Assistant Professor, Department pf physics NILM University, kaithal,Haryana, India

Abstract

The distinct magnetic characteristics and adaptability of Mn-Zn ferrites make them broadly applicable in a wide range of industries and applications. Temperature stability, high electricity resistivity, magnetic permeability, permittivity, saturation magnetization, and low power losses are among the characteristics of Mn-Zn ferrites. These ferrites particularly in the form of magnetic nanoparticles, have garnered significant interest in cancer research and therapy and the biomedical field. Researchers are keenly interested in the synthesis and characterization of Mn-Zn ferrites because of their diverse applications across various fields. Additionally, Mn-Zn ferrites are employed in electronic applications to produce transformers, transducers, and inductors. Additionally, magnetic fluids, sensors, and biosensors employ these ferrites. Mn-Zn ferrite is an extremely helpful substance for a variety of electronic and electrical uses. Nearly all home appliances, including mobile chargers, LED lights, TVs, refrigerators, juicer mixers, washing machines, irons, and microwaves, require it. In conclusion, Mn-Zn ferrites are an exceptionally versatile and valuable material, with applications ranging from cutting-edge medical research to the essential components found in everyday household appliances. Their distinct properties consistently fuel innovation and progress across various industries, establishing them as a fundamental element of modern technology

Keywords: Household appliances, LED lights, biomedical field., ferrimagnetic properties, magnetic permeability

[This article belongs to Research & Reviews : Journal of Physics ]

How to cite this article:
pooja rani, rohitash Kumar. A Review study of Mn-Zn Ferrite with Applications and Synthesis processes. Research & Reviews : Journal of Physics. 2025; 13(02):15-26.
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pooja rani, rohitash Kumar. A Review study of Mn-Zn Ferrite with Applications and Synthesis processes. Research & Reviews : Journal of Physics. 2025; 13(02):15-26. Available from: https://journals.stmjournals.com/rrjophy/article=2025/view=202878



References

  1. Sharifi I, Shokrollahi H, Doroodmand MM, Safi R. Magnetic and structural studies on CoFe2O4 nanoparticles synthesized by co-precipitation, normal micelles and reverse micelles methods. Journal of Magnetism and Magnetic Materials. 2012 May 1;324(10):1854-61.
  2. Shokrollahi HJ. A review of the magnetic properties, synthesis methods and applications of maghemite. Journal of Magnetism and Magnetic Materials. 2017 Mar 15;426:74-81.
  3. Shokrollahi H, Janghorban K. Influence of additives on the magnetic properties, microstructure and densification of Mn–Zn soft ferrites. Materials Science and Engineering: B. 2007 Aug 15;141(3):91-107.
  4. Sugimoto M. The past, present, and future of ferrites. Journal of the American Ceramic Society. 1999 Feb;82(2):269-80.
  5. Song Q, Zhang ZJ. Controlled synthesis and magnetic properties of bimagnetic spinel ferrite CoFe2O4 and MnFe2O4 nanocrystals with core–shell architecture. Journal of the American Chemical Society. 2012 Jun 20;134(24):10182-90.
  6. Skołyszewska B, Tokarz W, Przybylski K, Kakol Z. Preparation and magnetic properties of MgZn and MnZn ferrites. Physica C: Superconductivity. 2003 May 1;387(1-2):290-4.
  7. Henderson CM, Charnock JM, Plant DA. Cation occupancies in Mg, Co, Ni, Zn, Al ferrite spinels: a multi-element EXAFS study. Journal of Physics: Condensed Matter. 2007 Feb 2;19(7):076214.
  8. Tatarchuk TR, Bououdina M, Paliychuk ND, Yaremiy IP, Moklyak VV. Structural characterization and antistructure modeling of cobalt-substituted zinc ferrites. Journal of Alloys and Compounds. 2017 Feb 15;694:777-91.
  9. Deraz NM, Alarifi A. Structural, morphological and magnetic properties of nano-crystalline zinc substituted cobalt ferrite system. Journal of analytical and applied pyrolysis. 2012 Mar 1;94:41-7.
  10. Namai A, Yoshikiyo M, Yamada K, Sakurai S, Goto T, Yoshida T, Miyazaki T, Nakajima M, Suemoto T, Tokoro H, Ohkoshi SI. Hard magnetic ferrite with a gigantic coercivity and high frequency millimetre wave rotation. Nature communications. 2012 Jan;3(1):1035.
  11. Martirosyan KS, Martirosyan NS, Chalykh AE. Structure and properties of hard-magnetic barium, strontium, and lead ferrites. Inorganic materials. 2003 Aug;39:866-70.
  12. Anwar H, Maqsood A. Effect of sintering temperature on structural, electrical and dielectric parameters of Mn-Zn nano ferrites. Key Engineering Materials. 2012 May 22;510:163-70.
  13. Costa AC, Diniz AP, De Melo AG, Kiminami RH, Cornejo DR, Costa AA, Gama L. Ni–Zn–Sm nanopowder ferrites: Morphological aspects and magnetic properties. Journal of Magnetism and Magnetic Materials. 2008 Mar 1;320(5):742-9.
  14. Mansour S, Hemeda OM, Abdo MA, Nada WA. Improvement on the magnetic and dielectric behavior of hard/soft ferrite nanocomposites. Journal of Molecular Structure. 2018 Jan 15;1152:207-14.
  15. Sun T, Borrasso A, Liu B, Dravid V. Synthesis and characterization of nanocrystalline zinc manganese ferrite. Journal of the American Ceramic Society. 2011 May;94(5):1490-5.
  16. Kirchmayr HR. Permanent magnets and hard magnetic materials. Journal of Physics D: Applied Physics. 1996 Nov 14;29(11):2763..
  17. Chen A, Zhi Y, Bao Y. A study of BaTiO3-BaPbO3 ceramic composites. Journal of Physics: Condensed Matter. 1994 Sep 26;6(39):7921.
  18. Torkian S, Ghasemi A, Razavi RS. Magnetic properties of hard-soft SrFe10Al2O19/Co0. 8Ni0. 2Fe2O4 ferrite synthesized by one-pot sol–gel auto-combustion. Journal of Magnetism and Magnetic Materials. 2016 Oct 15;416:408-16.
  19. Heiligtag FJ, Niederberger M. The fascinating world of nanoparticle research. Materials today. 2013 Jul 1;16(7-8):262-71.
  20. Stäblein H. Hard ferrites and plastoferrites. Handbook of Ferromagnetic Materials. 1982 Jan 1;3:441-602.
  21. Pardavi-Horvath M. Microwave applications of soft ferrites. Journal of Magnetism and Magnetic Materials. 2000 Jun 2;215:171-83.
  22. Töpfer J, Mürbe J, Angermann A, Kracunovska S, Barth S, Bechtold F. Soft ferrite materials for multilayer inductors. International journal of applied ceramic technology. 2006 Nov;3(6):455-62.
  23. Miclea C, Tanasoiu C, Miclea CF, Gheorghiu A, Tanasoiu V. Soft ferrite materials for magnetic temperature transducers and applications. Journal of magnetism and magnetic materials. 2005 Apr 1;290:1506-9.
  24. Covaliu CI, Berger D, Matei C, Diamandescu L, Vasile E, Cristea C, Ionita V, Iovu H. Magnetic nanoparticles coated with polysaccharide polymers for potential biomedical applications. Journal of Nanoparticle Research. 2011 Nov;13:6169-80.
  25. Covaliu CI, Jitaru I, Paraschiv G, Vasile E, Biriş SŞ, Diamandescu L, Ionita V, Iovu H. Core–shell hybrid nanomaterials based on CoFe2O4 particles coated with PVP or PEG biopolymers for applications in biomedicine. Powder technology. 2013 Mar 1;237:415-26.
  26. Carey MJ, Maat S, Rice P, Farrow RF, Marks RF, Kellock A, Nguyen P, Gurney BA. Spin valves using insulating cobalt ferrite exchange-spring pinning layers. Applied physics letters. 2002 Aug 5;81(6):1044-6.
  27. Kaczmarek WA, Ninham BW. Application of mechanochemistry in ferrite materials technology. Le Journal de Physique IV. 1997 Mar 1;7(C1):C1-47.
  28. Zapata A, Herrera G. Effect of zinc concentration on the microstructure and relaxation frequency of Mn–Zn ferrites synthesized by solid state reaction. Ceramics International. 2013 Sep 1;39(7):7853-60.
  29. Yan QY, Gambino RJ, Sampath S. Plasma-sprayed MnZn ferrites with insulated fine grains and increased resistivity for high-frequency applications. IEEE transactions on magnetics. 2004 Sep 13;40(5):3346-51.
  30. Kogias G, Holz D, Zaspalis V. New MnZn ferrites with high saturation flux density. Journal of the Japan Society of Powder and Powder Metallurgy. 2014 Mar 31;61(S1):S201-3.
  31. Xing Q, Peng Z, Wang C, Fu Z, Fu X. Doping effect of Y3+ ions on the microstructural and electromagnetic properties of Mn–Zn ferrites. Physica B: Condensed Matter. 2012 Feb 1;407(3):388-92.
  32. Babayan V, Kazantseva NE, Moučka R, Sapurina I, Spivak YM, Moshnikov VA. Combined effect of demagnetizing field and induced magnetic anisotropy on the magnetic properties of manganese–zinc ferrite composites. Journal of Magnetism and Magnetic materials. 2012 Jan 1;324(2):161-72..
  33. Sláma J, Šoka M, Grusková A, Dosoudil R, Jančárik V, Degmová J. Magnetic properties of selected substituted spinel ferrites. Journal of Magnetism and magnetic Materials. 2013 Jan 1;326:251-6.
  34. Köseoğlu Y, Bay M, Tan M, Baykal A, Sözeri H, Topkaya R, Akdoğan N. Magnetic and dielectric properties of Mn 0.2 Ni 0.8 Fe 2 O 4 nanoparticles synthesized by PEG-assisted hydrothermal method. Journal of Nanoparticle Research. 2011 May;13:2235-44.
  35. Venturini J, Tonelli AM, Wermuth TB, Zampiva RY, Arcaro S, Viegas AD, Bergmann CP. Excess of cations in the sol-gel synthesis of cobalt ferrite (CoFe2O4): A pathway to switching the inversion degree of spinels. Journal of Magnetism and Magnetic Materials. 2019 Jul 15;482:1-8.
  36. Bae S, Hong YK, Lee JJ, Jalli J, Abo GS, Lyle A, Choi BC, Donohoe GW. High Q Ni-Zn-Cu ferrite inductor for on-chip power module. IEEE Transactions on Magnetics. 2009 Sep 22;45(10):4773-6.
  37. Zhao DL, Lv Q, Shen ZM. Fabrication and microwave absorbing properties of Ni–Zn spinel ferrites. Journal of Alloys and Compounds. 2009 Jul 8;480(2):634-8.
  38. Su H, Zhang H, Tang X, Wei X. Effects of calcining and sintering parameters on the magnetic properties of high-permeability MnZn ferrites. IEEE transactions on magnetics. 2005 Nov 14;41(11):4225-8.
  39. Su H, Zhang H, Tang X, Jing Y, Zhong Z. Complex permeability and permittivity spectra of polycrystalline Ni–Zn ferrite samples with different microstructures. Journal of alloys and compounds. 2009 Jul 29;481(1-2):841-4.
  40. Park SH, Ahn WK, Kum JS, Ji JK, Kim KH, Seong WM. Electromagnetic properties of dielectric and magnetic composite material for antenna. Electronic Materials Letters. 2009 Jun;5:67-71.
  41. Razzitte AC, Jacobo SE, Fano WG. Magnetic properties of MnZn ferrites prepared by soft chemical routes. Journal of Applied Physics. 2000 May 1;87(9):6232-4.
  42. Duan Z, Tao X, Xu J. Characterization of as-deposited and sintered Mn0. 5Zn0. 5Fe2O4 films formed by sol-gel. Ferroelectrics. 2018 May 19;528(1):131-8.
  43. Masthoff IC, Gutsche A, Nirschl H, Garnweitner G. Oriented attachment of ultra-small Mn (1− x) Zn x Fe 2 O 4 nanoparticles during the non-aqueous sol–gel synthesis. CrystEngComm. 2015;17(12):2464-70.
  44. Liu D, Gao S, Jin R, Wang F, Chu X, Gao T, Wang Y. Enhanced soft magnetic properties of iron powders through coating MnZn ferrite by one-step sol–gel synthesis. Chinese Physics B. 2019 May 1;28(5):057503.
  45. Jabbar R, Sabeeh SH, Hameed AM. Structural, dielectric and magnetic properties of Mn+ 2 doped cobalt ferrite nanoparticles. Journal of Magnetism and Magnetic Materials. 2020 Jan 15;494:165726.
  46. Irfan S, Ajaz-un-Nabi M, Jamil Y, Amin N. Synthesis of Mn1-xZnxFe2O4 ferrite powder by co-precipitation method. InIOP Conference Series: Materials Science and Engineering 2014 Jun 17 (Vol. 60, No. 1, p. 012048). IOP Publishing.
  47. Mathur P, Thakur A, Singh M. Processing of high density manganese zinc nanoferrites by co-precipitation method. Zeitschrift für Physikalische Chemie. 2007 Jun 1;221(7):887-95.
  48. Mathur P, Thakur A, Singh M. Study of low-temperature sintered nano-crystallite Mn-Cu-Zn ferrite prepared by co-precipitation method. Modern Physics Letters B. 2007 Sep 10;21(21):1425-30.
  49. Makovec D, Drofenik M, Žnidaršič A. Hydrothermal synthesis of manganese zinc ferrite powders from oxides. Journal of the American Ceramic Society. 1999 May;82(5):1113-20.
  50. Sanatombi S, Sumitra S, Ibetombi S. Influence of sintering on the structural, electrical, and magnetic properties of Li–Ni–Mn–Zn ferrite synthesized by citrate precursor method. Iranian Journal of Science and Technology, Transactions A: Science. 2018 Dec;42:2397-406.
  51. Kogias G, Zaspalis VT. Temperature stable MnZn ferrites for applications in the frequency region of 500 kHz. Ceramics International. 2016 May 1;42(6):7639-46.
  52. Mohseni H, Shokrollahi H, Sharifi I, Gheisari K. Magnetic and structural studies of the Mn-doped Mg–Zn ferrite nanoparticles synthesized by the glycine nitrate process. Journal of Magnetism and Magnetic Materials. 2012 Nov 1;324(22):3741-7.
  53. Feng J, Xiong R, Liu Y, Su F, Zhang X. Preparation of cobalt substituted zinc ferrite nanopowders via auto-combustion route: an investigation to their structural and magnetic properties. Journal of Materials Science: Materials in Electronics. 2018 Nov;29(21):18358-71.
  54. Košak A, Makovec D, Žnidaršič A, Drofenik M. Preparation of MnZn-ferrite with microemulsion technique. Journal of the European Ceramic Society. 2004 Jan 1;24(6):959-62.
  55. Sickafus K.E, Wills J.M, Grimes N.W. Structure of spinel. J. Am. Ceram. Soc. 2004; 82: 3279–3292,
  56. Li M, Fang H, Li H, Zhao Y, Li T, Pang H, Tang J, Liu X. Synthesis and characterization of MnZn ferrite nanoparticles with improved saturation magnetization. Journal of Superconductivity and Novel Magnetism. 2017 Aug;30:2275-81.
  57. Fujita A, Gotoh S. Temperature dependence of core loss in Co-substituted MnZn ferrites. Journal of applied physics. 2003 May 15;93(10):7477-9.
  58. Wang SF, Hsu YF, Chen CH. Effects of Nb 2 O 5, TiO 2, SiO 2, and CaO additions on the loss characteristics of Mn-Zn Ferrite. Journal of Electroceramics. 2014 Dec;33:172-9.
  59. Fujita A, Gotoh S. Temperature dependence of core loss in Co-substituted MnZn ferrites. J. Appl. Phys. 2003; 93:7477–7479.
  60. Hua F, Yin C, Zhang H, Suo Q, Wang X, Peng H. Direct preparation of the nanocrystalline MnZn ferrites by using oxalate as precipitant. Journal of Materials Science and Chemical Engineering. 2015 Dec 17;3(12):23-9.
  61. Welch RG, Neamtu J, Rogalski MS, Palmer SB. Polycrystalline MnZn ferrite films prepared by pulsed laser deposition. Materials Letters. 1996 Dec 1;29(4-6):199-203.
  62. Maisnam M, Phanjoubam S. Frequency dependence of electrical and magnetic properties of Li–Ni–Mn–Co ferrites. Solid state communications. 2012 Feb 1;152(4):320-3.
  63. Verma A, Alam MI, Chatterjee R, Goel TC, Mendiratta RG. Development of a new soft ferrite core for power applications. Journal of Magnetism and Magnetic Materials. 2006 May 1;300(2):500-5.
  64. Liu J, Mei Y, Li X, Lu GQ. Effects of MnZn ferrite doping on magnetic and electrical properties of NiZnCu ferrite toroid cores for power applications. In2018 19th International Conference on Electronic Packaging Technology (ICEPT) 2018 Aug 8 (pp. 965-968). IEEE.
  65. Tsakaloudi V, Zaspalis V. Synthesis of a low loss Mn–Zn ferrite for power applications. Journal of Magnetism and Magnetic Materials. 2016 Feb 15;400:307-10.
  66. Patel J, Parekh K, Upadhyay RV. Performance of Mn-Zn ferrite magnetic fluid in a prototype distribution transformer under varying loading conditions. International Journal of Thermal Sciences. 2017 Apr 1;114:64-71.
  67. Latorre-Esteves M, Cortes A, Torres-Lugo M, Rinaldi C. Synthesis and characterization of carboxymethyl dextran-coated Mn/Zn ferrite for biomedical applications. Journal of Magnetism and Magnetic Materials. 2009 Oct 1;321(19):3061-6.
  68. Nakagawa S, Saito S, Kamiki T, Kong SH. Mn–Zn spinel ferrite thin films prepared by high rate reactive facing targets sputtering. Journal of applied physics. 2003 May 15;93(10):7996-8.
  69. Tsakaloudi V, Kogias G, Zaspalis VT. Process and material parameters towards the design of fast firing cycles for high permeability MnZn ferrites. Journal of alloys and compounds. 2014 Mar 5;588:222-7.
  70. Rahaman MD, Nahar KK, Khan MN, Hossain AA. Synthesis, structural, and electromagnetic properties of Mn0. 5Zn0. 5− xMgxFe2O4 (x= 0.0, 0.1) polycrystalline ferrites. Physica B: Condensed Matter. 2016 Jan 15;481:156-64.
  71. Joseyphus RJ, Narayanasamy A, Shinoda K, Jeyadevan B, Tohji K. Synthesis and magnetic properties of the size-controlled Mn–Zn ferrite nanoparticles by oxidation method. Journal of Physics and Chemistry of Solids. 2006 Jul 1;67(7):1510-7.
  72. Jafarnejad E, Khanahmadzadeh S, Ghanbary F, Enhessari M. Synthesis, characterization and optical band gap of pirochromite (MgCr2O4) nanoparticles by stearic acid sol-gel method. Current Chemistry Letters. 2016;5(4):173-80.
  73. Enhessari M, Parviz A, Ozaee K, Karamali E. Magnetic properties and heat capacity of CoTiO3 nanopowders prepared by stearic acid gel method. Journal of Experimental Nanoscience. 2010 Feb 1;5(1):61-8.
  74. Ma M, Zhang Y, Li X, Fu D, Zhang H, Gu N. Synthesis and characterization of titania-coated Mn Zn ferrite nanoparticles. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2003 Aug 29;224(1-3):207-12.
  75. Goldman A, Laing AM. A new process for coprecipitation of ferrites. Le Journal de Physique Colloques. 1977 Apr 1;38(C1):C1-297.
  76. Thakur P, Sharma R, Kumar M, Katyal SC, Barman PB, Sharma V, Sharma P. Structural, morphological, magnetic and optical study of co-precipitated Nd3+ doped Mn-Zn ferrite nanoparticles. Journal of Magnetism and Magnetic Materials. 2019 Jun 1;479:317-25.
  77. Yadav N, Kumar A, Rana PS, Rana DS, Arora M, Pant RP. Finite size effect on Sm3+ doped Mn0. 5Zn0. 5SmxFe2− xO4 (0≤ x≤ 0.5) ferrite nanoparticles. Ceramics International. 2015 Aug 1;41(7):8623-9.
  78. Kumar S, Shinde TJ, Vasambekar PN. Study of conduction phenomena in indium substituted Mn–Zn nano-ferrites. Journal of Magnetism and Magnetic Materials. 2015 Apr 1;379:179-85.
  79. Haralkar SJ, Kadam RH, More SS, Shirsath SE, Mane ML, Patil S, Mane DR. Intrinsic magnetic, structural and resistivity properties of ferromagnetic Mn0. 5Zn0. 5AlxFe2− xO4 nanoparticles. Materials Research Bulletin. 2013 Mar 1;48(3):1189-96.
  80. Duan Z, Xu J. Effects of sol concentration on the structure and magnetic properties of sol-gel MnZn ferrites. Integrated Ferroelectrics. 2018 Jun 13;190(1):112-9.
  81. Duan Z, Tao X, Xu J. Characterization of as-deposited and sintered Mn0. 5Zn0. 5Fe2O4 films formed by sol-gel. Ferroelectrics. 2018 May 19;528(1):131-8.
  82. Gabal MA, Al-Luhaibi RS, Al Angari YM. Mn–Zn nano-crystalline ferrites synthesized from spent Zn–C batteries using novel gelatin method. Journal of hazardous materials. 2013 Feb 15;246:227-33.
  83. Jalaiah K, Babu KV. Structural, magnetic and electrical properties of nickel doped Mn-Zn spinel ferrite synthesized by sol-gel method. Journal of Magnetism and Magnetic Materials. 2017 Feb 1;423:275-80.
  84. Phong PT, Nam PH, Manh DH, Tung DK, Lee IJ, Phuc NX. Studies of the magnetic properties and specific absorption of Mn 0.3 Zn 0.7 Fe 2 O 4 nanoparticles. Journal of Electronic Materials. 2015 Jan;44:287-94.
  85. Yang G, Park SJ. Conventional and microwave hydrothermal synthesis and application of functional materials: A review. Materials. 2019 Apr 11;12(7):1177.
  86. Praveena K, Katlakunta S, Virk HS. Structural and magnetic properties of Mn-Zn ferrites synthesized by microwave-hydrothermal process. Solid State Phenomena. 2015 Jul 20;232:45-64.
  87. Valenzuela R. Novel applications of ferrites. Physics Research International. 2012;2012(1):591839.
  88. Wang Z, Wu A, Colombi Ciacchi L, Wei G. Recent advances in nanoporous membranes for water purification. Nanomaterials. 2018 Jan 25;8(2):65.
  89. Kharbanda P, Madaan T, Sharma I, Vashishtha S, Kumar P, Chauhan A, Mittal S, Bangruwa JS, Verma V. Ferrites: magnetic materials as an alternate source of green electrical energy. Heliyon. 2019 Jan 1;5(1).
  90. Pr3+-or Sm3+-substituted cobalt–zinc ferrite on photodegradation of methyl orange and cytotoxicity tests. Journal of Rare Earths. 2019 Dec 1;37(12):1288-95.
  91. Bhukal S, Dhiman M, Bansal S, Tripathi MK, Singhal S. Substituted Co–Cu–Zn nanoferrites: synthesis, fundamental and redox catalytic properties for the degradation of methyl orange. RSC advances. 2016;6(2):1360-75.
  92. Raina O, Manimekalai R. Photocatalysis of cobalt zinc ferrite nanorods under solar light. Research on Chemical Intermediates. 2018 Oct;44(10):5941-51.
  93. Kefeni KK, Mamba BB, Msagati TA. Application of spinel ferrite nanoparticles in water and wastewater treatment: a review. Separation and Purification Technology. 2017 Nov 29;188:399-422.
  94. Fan G, Tong J, Li F. Visible-light-induced photocatalyst based on cobalt-doped zinc ferrite nanocrystals. Industrial & engineering chemistry research. 2012 Oct 24;51(42):13639-47.
  95. Samadi S, Khalili E, Allahgholi Ghasri MR. Degradation of methyl red under visible light using N, F-TiO 2/SiO 2/rGO nanocomposite. Journal of Electronic Materials. 2019 Dec;48:7836-45.
  96. Shetty K, Renuka L, Nagaswarupa HP, Nagabhushana H, Anantharaju KS, Rangappa D, Prashantha SC, Ashwini K. A comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: morphology, impedance and photocatalytic studies. Materials Today: Proceedings. 2017 Jan 1;4(11):11806-15.
  97. Lu AH, Salabas EE, Schüth F. Magnetic nanoparticles: synthesis, protection, functionalization, and application. Angewandte chemie international edition. 2007 Feb 12;46(8):1222-44.
  98. Ali A, Zafar H, Zia M, ul Haq I, Phull AR, Ali JS, Hussain A. Synthesis, characterization, applications, and challenges of iron oxide nanoparticles. Nanotechnology, science and applications. 2016 Aug 19:49-67.
  99. Sivashankar R, Sathya AB, Vasantharaj K, Sivasubramanian V. Magnetic composite an environmental super adsorbent for dye sequestration–A review. Environmental Nanotechnology, Monitoring & Management. 2014 Nov 1;1:36-49.
  100. Lata S, Samadder SR. Removal of arsenic from water using nano adsorbents and challenges: a review. Journal of environmental management. 2016 Jan 15;166:387-406.
  101. Lee H, Shin TH, Cheon J, Weissleder R. Recent developments in magnetic diagnostic systems. Chemical reviews. 2015 Oct 14;115(19):10690-724.
  102. Lee N, Yoo D, Ling D, Cho MH, Hyeon T, Cheon J. Iron oxide based nanoparticles for multimodal imaging and magnetoresponsive therapy. Chemical reviews. 2015 Oct 14;115(19):10637-89.
  103. Ling D, Lee N, Hyeon T. Chemical synthesis and assembly of uniformly sized iron oxide nanoparticles for medical applications. Accounts of chemical research. 2015 May 19;48(5):1276-85.
  104. Gawande MB, Goswami A, Asefa T, Guo H, Biradar AV, Peng DL, Zboril R, Varma RS. Core–shell nanoparticles: synthesis and applications in catalysis and electrocatalysis. Chemical Society Reviews. 2015;44(21):7540-90.
  105. Gawande MB, Monga Y, Zboril R, Sharma RK. Silica-decorated magnetic nanocomposites for catalytic applications. Coordination Chemistry Reviews. 2015 Apr 1;288:118-43.
  106. Farheen A, Singh R. FMR and magnetic studies of RF-sputtered Mn-Zn ferrite thin films. Journal of Superconductivity and Novel Magnetism. 2019 Aug 15;32:2679-86.
  107. Tokatlidis S, Kogias G, Zaspalis VT. Low loss MnZn ferrites for applications in the frequency region of 1–3 MHz. Journal of Magnetism and Magnetic Materials. 2018 Nov 1;465:727-35.
  108. Fiorillo F, Beatrice C, Bottauscio O, Carmi E. Eddy-current losses in Mn-Zn ferrites. IEEE Transactions on Magnetics. 2013 Aug 28;50(1):1-9.
  109. Reddy DH, Yun YS. Spinel ferrite magnetic adsorbents: alternative future materials for water purification?. Coordination Chemistry Reviews. 2016 May 15;315:90-111.
  110. Boutra B, Güy N, Özacar M, Trari M. Magnetically separable MnFe2O4/TA/ZnO nanocomposites for photocatalytic degradation of Congo Red under visible light. Journal of Magnetism and Magnetic Materials. 2020 Mar 1;497:165994.
  111. Bifa JI, Changan TI, Zhang Q, Dongdong JI, Jie YA, Jinsong XI, Jingyu SI. Magnetic properties of samarium and gadolinium co-doping Mn-Zn ferrites obtained by sol-gel auto-combustion method. Journal of Rare Earths. 2016 Oct 1;34(10):1017-23.
  112. Jeyadevan B, Chinnasamy CN, Shinoda K, Tohji K, Oka H. Mn–Zn ferrite with higher magnetization for temperature sensitive magnetic fluid. Journal of Applied Physics. 2003 May 15;93(10):8450-2.
  113. measurements and equivalent electrical circuit modeling. IEEE Transactions on Power Electronics. 2018 Feb 5;33(12):10723-35.
  114. Stergiou CA, Zaspalis V. Cobalt-induced performance instabilities of Mn–Zn ferrite cores. IEEE Transactions on Magnetics. 2018 Jun 6;54(8):1-8.
  115. Lukovic MD, Nikolic MV, Blaz NV, Zivanov LD, Aleksic OS, Lukic LS. Mn-Zn ferrite round cable EMI suppressor with deep grooves and a secondary short circuit for different frequency ranges. IEEE transactions on magnetics. 2013 Feb 20;49(3):1172-7.
  116. Witkin D, Patel D, Sandkulla D, Liu K. Novel Tests for the As-Manufactured Strength of Mn-Zn Ferrite Inductor Cores. American Institute of Aeronautics and Astronautics. 2012:1–14.
  117. Tsakaloudi V, Papazoglou E, Zaspalis VT. Microwave firing of MnZn-ferrites. Materials Science and Engineering: B. 2004 Feb 15;106(3):289-94.
  118. Jeyadevan B, Chinnasamy CN, Shinoda K, Tohji K, Oka H. Mn–Zn ferrite with higher magnetization for temperature sensitive magnetic fluid. Journal of Applied Physics. 2003 May 15;93(10):8450-2.
  119. Thakur P, Sharma R, Kumar M, Katyal SC, Negi NS, Thakur N, Sharma V, Sharma P. Superparamagnetic La doped Mn–Zn nano ferrites: dependence on dopant content and crystallite size. Materials Research Express. 2016 Jun 29;3(7):075001.
  120. Sridhar CS, Lakshmi CS, Govindraj G, Bangarraju S, Satyanarayana L, Potukuchi DM. Structural, morphological, magnetic and dielectric characterization of nano-phased antimony doped manganese zinc ferrites. Journal of Physics and Chemistry of Solids. 2016 May 1;92:70-84.
  121. Tokatlidis S, Kogias G, Zaspalis VT. Low loss MnZn ferrites for applications in the frequency region of 1–3 MHz. Journal of Magnetism and Magnetic Materials. 2018 Nov 1;465:727-35.
  122. Fang X, Wu R, Peng L, Sin JK. A novel silicon-embedded toroidal power inductor with magnetic core. IEEE Electron device letters. 2013 Jan 14;34(2):292-4.
  123. Waqas H, Qureshi AH, Shahzad M. Effect of firing temperature on the electromagnetic properties of electronic transformer cores developed by using nanosized Mn–Zn ferrite powders. Acta Metallurgica Sinica (English Letters). 2015 Feb;28:159-63..
  124. Liu J, Mei Y, Li X, Lu GQ. Effects of MnZn ferrite doping on magnetic and electrical properties of NiZnCu ferrite toroid cores for power applications. In2018 19th International Conference on Electronic Packaging Technology (ICEPT) 2018 Aug 8 (pp. 965-968). IEEE.
  125. Blaž NV, Luković MD, Nikolic MV, Aleksić OS, Živanov LD. Heterotube Mn-Zn ferrite bundle EMI suppressor with different magnetic coupling configurations. IEEE Transactions on Magnetics. 2014 Mar 11;50(8):1-7.
  126. Ahmad R, Gul IH, Zarrar M, Anwar H, Khan Niazi MB, Khan A. Improved electrical properties of cadmium substituted cobalt ferrites nano-particles for microwave application. Journal of magnetism and magnetic materials. 2016 May 1;405:28-35.
  127. Zahi S. Nickel–zinc ferrite fabricated by sol–gel route and application in high-temperature superconducting magnetic energy storage for voltage sag solving. Materials & Design. 2010 Apr 1;31(4):1848-53.
  128. Dar MA, Majid K, Najar MH, Kotnala RK, Shah J. Synthesis and characterization of Li0. 5Fe2. 5-xGdxO4 ferrite nano-particles as a potential candidate for microwave device applications. Materials & Design. 2016 Jan 15;90:443-52.
  129. Khademi F, Poorbafrani A, Kameli P, Salamati H. Structural, magnetic and microwave properties of Eu-doped barium hexaferrite powders. Journal of superconductivity and novel magnetism. 2012 Feb;25:525-31.
  130. Dobák S, Beatrice C, Fiorillo F, Tsakaloudi V, Ragusa C. Magnetic loss decomposition in Co-doped Mn-Zn ferrites. IEEE Magnetics Letters. 2018 Nov 13;10:1-5.
  131. Sun B, Chen F, Yang W, Shen H, Xie D. Effects of nano-TiO2 and normal size TiO2 additions on the microstructure and magnetic properties of manganese–zinc power ferrites. Journal of magnetism and magnetic materials. 2014 Jan 1;349:180-7.
  132. Kharbanda P, Madaan T, Sharma I, Vashishtha S, Kumar P, Chauhan A, Mittal S, Bangruwa JS, Verma V. Ferrites: magnetic materials as an alternate source of green electrical energy. Heliyon. 2019 Jan 1;5(1).
  133. Peymani-Motlagh SM, Moeinian N, Rostami M, Fasihi-Ramandi M, Sobhani-Nasab A, Rahimi-Nasrabadi M, Eghbali-Arani M, Ganjali MR, Jesionowski T, Ehrlich H, Karimi MA. Effect of Gd3+-, Pr3+-or Sm3+-substituted cobalt–zinc ferrite on photodegradation of methyl orange and cytotoxicity tests. Journal of Rare Earths. 2019 Dec 1;37(12):1288-95.
  134. Phan TL, Tran N, Kim DH, Dang NT, Manh DH, Bach TN, Liu CL, Lee BW. Magnetic and magnetocaloric properties of Zn 1− x Co x Fe 2 O 4 nanoparticles. Journal of Electronic Materials. 2017 Jul;46:4214-26.
Regular Issue Subscription Review Article
Volume 13
Issue 02
Received 09/07/2024
Accepted 23/08/2024
Published 25/02/2025
Publication Time 231 Days
Total Visits: 47


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