Izvestiya of Saratov University.

Physics

ISSN 1817-3020 (Print)
ISSN 2542-193X (Online)


For citation:

Voronin D. V., Sadovnikov A. V., Beginin E. N., Shchukin D. G., Gorin D. A. Magnetic Composites with Embedded Magnetite Nanoparticles: Preparation, Control of Physical Properties, Applications. Izvestiya of Saratov University. Physics , 2013, vol. 13, iss. 2, pp. 50-54. DOI: 10.18500/1817-3020-2013-13-2-50-54

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Full text:
(downloads: 237)
Language: 
Russian
UDC: 
537.6; 544.7

Magnetic Composites with Embedded Magnetite Nanoparticles: Preparation, Control of Physical Properties, Applications

Autors: 
Voronin Denis Viktorovich, Saratov State University
Sadovnikov Alexander Vladimirovich, Saratov State University
Beginin Evgeny Nikolaevich, Saratov State University
Shchukin Dmitry Georgievich, Max Plank Institute of colloids and interfaces
Gorin Dmitry Aleksandrovich, Saratov State University
Abstract: 

The formation of nanocomposites with embedded magnetite nanoparticles using layer-by-layer deposition is described in this review. It was shown, that physical properties of these composites are controllable by the variation of the magnetic nanoparticles layers number in their structure. The review of some practical application of magnetic nanocomposite materials based on their controllable properties was carried out as well.

Reference: 
  1. Iler R. K. Multilayers of colloidal particles // J. Colloid Interface Sci. 1966. Vol. 21, № 6. P. 569–594.
  2. Decher G., Hong J. D., Schmitt J. Buildup of ultrathin multilayer fi lms by a self-assembly process : III. Consecutively alternating adsorption of anionic and cationic polyelectrolytes on charged surfaces // Thin Solid Films. 1992. Vol. 210–211, № 2. P. 831–835.
  3. Lvov Y., Essler F., Decher G. Combination of polycation/ polyanion self-assembly and Langmuir–Blodgett transfer for the construction of superlattice fi lms // J. Phys. Chem. 1993. Vol. 97, № 51. P. 13773–13777
  4. Decher G. Fuzzy Nanoassemblies: Toward Lay ered Polymeric Multicomposites // Science. 1997. Vol. 277, № 5330. P. 1232–1237.
  5. Möhwald H. From Langmuir mo nolayers to nanocapsules // Colloids Surf. A. 2000. Vol. 171, № 1–3. P. 25–31. 
  6. Sato K., Suzuki I., Anzai J.-I. Preparation of Polyelectrolyte-Layered Assemblies Containing Cyclodextrin and Their Binding Properties // Langmuir. 2003. Vol. 19, № 18. P. 7406–7412.
  7. Cui T., Hua F., Lvov Y. Lithographic approach to pattern multiple nanoparticle thin fi lms prepared by layer-bylayer self-assembly for microsystems // Sens. Actuators. A. 2004. Vol. 114, № 2–3. P. 501–504.
  8. Khom utov G. B. Interfacially formed organized planar inorganic, polymeric and composite nanostructures // Adv. Colloid Interface Sci . 2004. Vol. 111, № 1–2. P. 79–116.
  9. Jomaa H. W., Schlenoff J. B. Salt-Induced Polyelectrolyte Interdiffusion in Multilayered Films : A Neutron Refl ectivity Study // Macromolecules. 2005. Vol. 38, № 20. P. 8473–8480.
  10. Kolasińska M., Warszyński P. The effect of support material and conditioning on w ettability of PAH/PSS multilayer fi lms // Bioelectrochemistry. 2005. Vol. 66, № 1–2. P. 65–70.
  11. Lee C.-W., Park H.-S., Gong M.-S. Humidity sensitive properties of quaternary ammonium salts containing polyelect rolytes crosslinked with 2-oxazoline crosslinker // Sens. Actuators, B. 2005. Vol. 109, № 2. P. 256–263.
  12. Yang Y., Yang X., Liu Y.-L., Liu Z.-M., Yang H.-F., Shen G.-L., Y u R.-Q. Optical sensor for lithocholic acid based on multilayered assemblies from polyelectrolyte and cyclodextrin // J. Photochem. Photobiol. A. 2005. Vol. 171, № 2. P. 137–144.
  13. G rigoriev D., Gorin D., Sukhorukov G. B., Yashchenok A., Maltseva E., Möhwald H. Polyelectrolyte/magnetite Nanoparticle Multilayers : Preparation and Structure Characterization // Langmui r. 2007. Vol. 23, № 24. P. 12388–12396.
  14. Kolasińska M., Krastev R., Warszyński P. Characteristics of polyelectrolyte multilayers : Effect of PEI anchoring layer and posttreatment after deposition // J. Colloid Interface Sc i. 2007. Vol. 305, № 1. P. 46–56.
  15. Gorin D. A., Yashchenok A. M., Koksharov Y. A., Neveshkin A. A., Serdobintsev A. A., Grigoriev D. O., Khomutov G. B. Surface morphology and optical and magnetic properties of polyelectrolyte/magnetite nanoparticl es nanofi lms // Tech. Phys. 2009. Vol. 54, № 11. P. 1675–1680.
  16. Dincer I., Tozkoparan O., German S. V., Markin A. V., Yildirim O., Khomutov G. B., Gorin D. A., Venig S. B., Elerman Y. Effect of the number of iron oxide nanoparticl e layers on the magnetic properties of nanocomposite LbL assemblies // J. Magn. Magn. Mater. 2012. Vol. 324, № 19. P. 2958–2963.
  17. Schmitt J., Decher G., Dressick W. J., Brandow S. L., Geer R. E., Shashidhar R., Calvert J . M. Metal nanoparticle/polymer superlattice fi lms : Fabrication and control of layer structure // Adv. Mater. 1997. Vol. 9, № 1. P. 61–65.
  18. Correa-Duarte M. A., Giersig M., Kotov N. A., Liz-Marzán L. M. Control of Packing Order of Self-Assembled Monolayers of Magnetite Nanoparti cles with and without SiO2 Coating by Microwave Irradiation // Langmuir. 1998. Vol. 14, № 22. P. 6430–6435.
  19. Wei J., Liu J., Li S. Electromagnetic and microwave absorption properties of Fe3O4 magnetic fi lms plated on hollow glass spheres // J. Magn. Magn. Mater. 2007. Vol. 312, № 2. P. 414–417.
  20. Dai Q., Berman D., Virwani K., Frommer J., Jubert P.-O., Lam M., Topuria T., Imaino W., Nelson A. Self-Assembled Ferrimagnet−Polymer Composites for Magnetic Recording Media // Nano Lett. 2010. Vol. 10, № 8. P. 3216–3221.
  21. Makarov D. , Brombacher C., Liscio F., Maret M., Parlinska M., Meier S., Kappenberger P., Albrecht M. FePt fi lms on self-assembled SiO2 particle arrays // J. Appl. Phys. 2008. Vol. 103, № 5. P. 053903-4.
  22. Yamaguchi M., Hyeon Kim K., Ikedaa S. Soft magnetic mater ials application in the RF range // J. Magn. Magn. Mater. 2006. Vol. 304, № 2. P. 208–213.
  23. Korenivski V., Van Dover R. B. Magnetic fi lm inductors for radio frequency applications // J. Appl . Phys. 1997. Vol. 82, № 10. P. 5247–5254.
  24. Lee C.-H., Shin D.-H., Ahn D.-H., Nam S.-E., Kim H.-J. Fabrication of thin film inductors using FeTaN soft magnetic fi lms // J. Appl. Phys. 1999. Vol. 85, № 8. P. 4898–4900.
  25. Žut ić I., Fabian J., Das Sarma S. Spintronics : Fundamentals and applications // Rev. Mod. Phys. 2004. Vol. 76, № 2. P. 323–410.
  26. Чеченин Н. Г. Магнитные наноструктуры и их применение : учеб. пособие. М. : Грант Виктория ТК, 2006. 166 c.
  27. Yashchenok A. M., Gorin D. A., Badylevich M., Serdobintsev A. A., Bedard M., Fedorenko Y. G., Khomutov G. B., Grigorie v D. O., Mohwald H. Impact of magnetite nanoparticle incorporation on optical and electrical properties of nanocomposite LbL assemblies // Phys. Ch em. Chem. Phys. 2010. Vol. 12, № 35. P. 10469–10475.
  28. Voronin D. V., Borisova D., Belova V., Gorin D. A., Shchukin D. G. Effect of Surface Functionalization of Metal Wire on Ele ctrophysical Properties of Inductive Elements // Langmuir. 2012. Vol. 28, № 33. P. 12275–12281.
  29. Sorokina O. N., Bychkova A. V., Kova rskii A. L. Analysis of the ferromagnetic resonance spectra of aggregates of magnetite nanoparticles formed by a magnetic fi eld // Russ. J. Phys. Chem. B. 2009. Vol. 3, № 2. P. 257–261.
  30. Caprile A., Coisson M., Fiorillo F., Kabos P., Manu O. M., Olivetti E. S., Olariu, M. Pasquale M. A., Scarlatache V. A. Microwave Behavior of Polymer Bonded Iron Oxide Nanoparticles // IEEE Trans. Magn. 2012. Vol. 48, № 11. P. 3394-3397.
  31. Alvarado S. F., Eib W., Meier F., Pierce D. T., Sattler K., Siegmann H. C., Remeika J. P. Observation of SpinPolarized Electron Levels in Ferrites // Phys. Rev. Lett. 1975. Vol. 34, № 6. P. 319–322.
  32. Huang Z. C., Hu X. F., Xu Y. X., Zhai Y., Xu Y. B., Wu J., Zhai H. R. Magnetic properties of ultrathin single crystal Fe3O4 fi lm on InAs(100) by ferromagnetic resonance // J. Appl. Phys. 2012. Vol. 111, № 7. P. 07C108-3.
  33. Fernandez-Pacheco A., Orna J., De Teresa J. M., Algarabel P. A., Morellon L., Pardo J. A., Ibarra M. R., Kampert E., Zeitler U. High-fi eld Hall effect and magnetoresistance in Fe3O4 epitaxial thin fi lms up to 30 Tesla // Appl. Phys. Lett. 2009. Vol. 95, № 26. P. 262108-3.
  34. Zhai Y., Huang Z. C., Fu Y., Ni C., Lu Y. X., Xu Y. B., Wu J., Zhai H. R. Aniso tropy of ultrathin epitaxial Fe3O4 fi lms on GaAs(100) // J. Appl. Phys. 2007. Vol. 101, № 9. P. 09D126-3.
  35. Huang Z. C., Zhai Y., Lu Y. X., Li G. D., Wong P. K. J., Xu Y. B., Xu Y. X., Zhai H. R. The inte rface effect of the magnetic anisotropy in ultrathin epitaxial Fe3O4 fi lm // Appl. Phys. Lett. 2008. Vol. 92, № 11. P. 113105-3.
  36. Demokritov S. O., Hillebrands B., Slavin A. N. Brillouin light scattering studies of confi ned spin waves : linear and nonlinear confi nement // Physics Reports. 2001. Vol. 348, № 6. P. 441–489.
  37. Demidov V. E., Demokritov S. O., Hillebrands B., Laufenberg M., Freitas P. P. Radiation of spin waves by a single micrometer-sized magnetic element // Appl. Phys. Lett. 2004. Vol. 85, № 14. P. 2866–2868
  38. Demokritov S. O., Demidov V. E. Micro-Brillouin Light Scattering Spectroscopy of Magnetic Nanostructures // IEEE Trans. Magn. 2008. Vol. 44, № 1. P. 6–12.
  39. Воронин Д. В., Садовников А. В., Щукин Д. Г., Горин Д. А., Бегинин Е. Н., Шараевский Ю. П., Ни- китов С. А. Исследование спектров тепловых магнонов в композитных материалах, содержащих наночастицы магнетита, методом бриллюэновского рассеяния света // Письма в ЖТФ. 2013. Т. 39, № 16. С. 6–13.