Prof. Dr. Dmitry Alexandrovich
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Prof. Dr. Dmitry Alexandrovich

Head of Department
Yaroslav-the-Wise Novgorod State University, Russia

Highest Degree
Ph.D. in Physical Science Engineering from Saint Petersburg State University, Russia

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Area of Interest:

Physical Science Engineering
100%
Piezoelectric Composites
62%
Ferromagnetic Resonances
90%
Thin Film Magnetics
75%
Microwave Devices
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
0
Abstracts
0

Selected Publications

  1. Filippov, D.A., T.O. Firsova, V.M. Laletin and N.N. Poddubnaya, 2017. The magnetoelectric effect in nickel-gallium arsenide-nickel structures. Tech. Phys. Lett., 43: 313-315.
  2. Filippov, D.A., G.S. Radchenko, T.O. Firsova and T.A. Galkina, 2017. A theory of the inverse magnetoelectric effect in layered magnetostrictive–piezoelectric structures. Phy. Solid State, 59: 878-884.
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  3. Filippov, D.A., G.S. Radchenko and V.M. Laletin, 2016. Magnetoelectric effect in layered disk-shaped magnetostrictive-piezoelectric structures: Theory and experiment. Phys. Solid State, 58: 508-514.
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  4. Radchenko, G.S., D.А. Filippov and V.М. Laletin, 2015. The multimodal magnetoelectric effect in the ring-type piezomagnetostrictive composite structures. Applied Phys. A, 121: 619-623.
  5. Filippov, D.A., V.M. Laletin and G.S. Radchenko, 2015. The magnetoelectric effect in the ring shape magnetostrictive-piezoelectric structures. Tech. Phys. Lett., 41: 807-819.
    CrossRef  |  Direct Link  |  
  6. Filippov, D.A., G.S. Radchenko, M.G. Radchenko and T.A. Galkina, 2015. Inverse multimodal magnetoelectric effect in piezomagnetostrictive rings. Phys. Solid State, 57: 694-699.
  7. Laletin, V.M., D.A. Filippov and T.O. Firsova, 2014. The nonlinear resonance magnetoelectric effect in magnetostrictive-piezoelectric structures. Tech. Phys. Lett., 40: 237-240.
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  8. Filippov, D.A., V.M. Laletin and T.O. Firsova, 2014. Nonlinear magnetoelectric effect in composite multiferroics. Phys. Solid State, 56: 980-984.
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  9. Filippov, D.A., T.A. Galichyan and V.M. Laletin, 2014. Magnetoelectric effect in bilayer magnetostrictive-piezoelectric structure: Theory and experiment. Applied Phys. A, 115: 1087-1091.
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  10. Filippov, D.A., T.A. Galichyan and V.M. Laletin, 2014. Influence of an interlayer bonding on the magnetoelectric effect in the layered magnetostrictive-piezoelectric structure. Applied Phys. A, 116: 2167-2171.
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  11. Filippov, D.A., V.M. Laletin and T.A. Galichyan, 2013. Magnetoelectric effect in a magnetostrictive-piezoelectric bilayer structure. Phys. Solid State, 55: 1840-1845.
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  12. Filippov, D. and T. Galichyan, 2013. Theory of magnetoelectric effect in a bilayer magnetostrictive-piezoelectric structure. Russian Phys. J., 56: 686-692.
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  13. Filippov, D.A., V.M. Laletin and G. Srinivasan, 2012. Low-frequency and resonance magnetoelectric effects in nickel ferrite-PZT bulk composites. Tech. Phys., 57: 44-47.
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  14. Filippov, D.A., T.A. Galkina, V.M. Laletin and G. Srinivasan, 2012. Voltage transformer based on inverse magnetoelectric effect. Tech. Phys. Lett., 38: 93-95.
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  15. Filippov, D.A., 2012. Magnetoelectric effect in thin-film magnetostriction-piezoelectric structures grown on a substrate. Phys. Solid State, 54: 1182-1185.
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  16. Filippov, D.A., T.A. Galkina, V.M. Laletin and G. Srinivasan, 2011. Inverse magnetoelectric effect in disk-shaped samples of ferrite piezoelectric composites. Phys. Solid State, Vol. 53. .
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  17. Filippov, D.A., T.A. Galkina and G. Srinivasan, 2010. Inverse magnetoelectric effect in ferrite-piezoelectric structures. Tech. Phys. Lett., 36: 984-986.
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  18. Filippov, D.A., G. Srinivasan and A. Gupta, 2008. Magnetoelectric effects in ferromagnetic films on ferroelectric substrates. J. Phys.: Condensed Matter, Vol. 20. .
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  19. Tatarenko, A.S., G. Srinivasan and D.A. Filippov, 2007. Magnetoelectric microwave attenuator. Elect. Lett., 43: 674-675.
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  20. Filippov, D.A., U. Laletsin and G. Srinivasan, 2007. Resonance magnetoelectric effects in magnetostrictive-piezoelectric three-layer structures. J. Applied Phys., Vol. 102. .
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  21. Srinivasan, G., C.P. De Vreugd, V.M. Laletin, N. Paddubnaya, M.I. Bichurin, V.M. Petrov and D.A. Filippov, 2005. Resonant magnetoelectric coupling in trilayers of ferromagnetic alloys and piezoelectric lead zirconate titanate: The influence of bias magnetic field. Phys. Rev. B, Vol. 71. 10.1103/PhysRevB.71.184423.
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  22. Filippov, D.A., M.I. Bichurin, C.W. Nan and J.M. Liu, 2005. Magnetoelectric effect in hybrid magnetostrictive-piezoelectric composites in the electromechanical resonance region. J. Applied Phys., Vol. 97. 10.1063/1.1929865.
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  23. Filippov, D.A., 2005. Theory of the magnetoelectric effect in ferromagnetic-piezoelectric heterostructures. Phys. Solid State, 47: 1118-1121.
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  24. Antonenkov, O.V., M.I. Bichurin, D.A. Filippov, V.M. Petrov and G. Srinivasan, 2005. Electric-field-induced shift of the magnetic resonance line in ferrite-piezoelectric composites. Tech. Phys. Lett., 31: 673-675.
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  25. Shi, Z., C.W. Nan, J.M. Liu, D.A. Filippov and M.I. Bichurin, 2004. Influence of mechanical boundary conditions and microstructural features on magnetoelectric behavior in a three-phase multiferroic particulate composite. Phys. Rev. B, Vol. 70. 10.1103/PhysRevB.70.134417.
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  26. Filippov, D.A., M.I. Bichurin, V.M. Petrov, V.M. Laletin, N.N. Poddubnaya and G. Srinivasan, 2004. Giant magnetoelectric effect in composite materials in the region of electromechanical resonance. Tech. Phys. Lett., 30: 6-8.
    CrossRef  |  Direct Link  |  
  27. Filippov, D.A., M.I. Bichurin, V.M. Petrov, V.M. Laletin and G. Srinivasan, 2004. Resonant amplification of the magnetoelectric effect in ferrite-piezoelectric composites. Phys. Solid State, 46: 1674-1680.
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  28. Filippov, D.A., 2004. Theory of magnetoelectric effect in ferromagnetic-piezoelectric bilayer structures. Tech. Phys. Lett., 30: 983-986.
    CrossRef  |  Direct Link  |  
  29. Filippov, D.A., 2004. Theory of magnetoelectric effect in ferrite-piezoelectric hybrid composites. Tech. Phys. Lett., 30: 351-353.
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  30. Filippov, D.A., 2004. Theory of magnetoelectric effect in double-layer ferromagnetic-piezoelectric structures. Russian Phys. J., 47: 1213-1217.
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  31. Filippov, D.A. and I.S. Nikiforov, 2004. Calculation of states of an ion Fe3 in crystal FeBO3. Int. J. Quant. Chem., 100: 13-15.
    CrossRef  |  Direct Link  |  
  32. Bichurin, M.I., D.A. Filippov, V.M. Petrov, V.M. Laletsin, N. Paddubnaya and G. Srinivasan, 2003. Resonance magnetoelectric effects in layered magnetostrictive-piezoelectric composites. Phys. Rev. B, Vol. 68. 10.1103/PhysRevB.68.132408.
    CrossRef  |  Direct Link  |  
  33. Nikiforov, I.S. and D.A. Filippov, 2002. Calculation of a power spectrum and definition of wave functions of an ion Cr3+ in antiferromagnetic crystal Cr2O3 in the model of a crystalline field. Int. J. Quant. Chem., 88: 676-680.
    CrossRef  |  Direct Link  |  
  34. Filippov, D.A. and I.S. Nikiforov, 2002. The energy spectrum of an ion Cr3+ in antiferromagnet Cr2O3. Ferroelectrics, 279: 45-55.
    CrossRef  |  Direct Link  |  
  35. Antonenkov, O.V., D.A. Filippov and I.S. Nikiforov, 2002. The theory of resonance magnetoelectric effect in Cr2O3 on the basis of the one-ion model. Ferroelectrics, 279: 57-65.
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  36. Filippov, D.A. and I.S. Nikiforov, 2000. Method for calculating crystal field potential in ionic compounds. Russian J. Phys. Chem., 74: 55-57.
  37. Bichurin, M.I. and D.A. Filippov, 1997. The microscopic mechanism of the magnetoelectric effect in the microwave range. Ferroelectric, 204: 225-232.
  38. Gurevich, L.E. and D.A. Filippov, 1982. Electromagnetic-waves in a polar semiconductor subjected to an external magnetic-field. Soviet Phys.: Semiconductors-USSR., 16: 1274-1275.