Vladimir R. Tuz，foreign professor of International Center of Future Science and State Key Laboratory of Integrated Optoelectronics, College of Electronic Science and engineering of Jilin University. Dr.  Vladimir graduated from Kharkov State University in Ukraine in 2005 with a doctorate in theoretical physics. He was a professor of Kharkov National University and chief researcher of the Institute of radio astronomy of the National Academy of Sciences of Ukraine.  He was also a senior research engineer of Samsung Electronics . Since 2016, he has taught in Jilin University,.

Education

1996   Diploma in Radio Physics (similar to MS degree) from Kharkiv State University, Ukraine.  Supervisor: prof. V. B. Kazanskiy
2005   Candidate of Physical and Mathematical Sciences Degree in Radiophysics (similar to Ph. D.) from V.N. Karazin Kharkiv National University, Ukraine. Supervisor: prof. V. B. Kazanskiy
2013  Doctor of Physical and Mathematical Sciences Degree in Radiophysics (similar to Dr. Habil.) from V.N. Karazin Kharkiv National University, Ukraine. Supervisor: prof. S. L. Prosvirnin

Research interest

Microwave technology, complex and random media, composite materials, electromagnetic calculation of photonic crystals and metamaterials, numerical methods of electromagnetics, nonlinear waves and solitons.

Selected Publications
1. P. Yu, V. Fesenko, V. Tuz, “Dispersion features of complex waves in a graphene-coated semiconductor nanowire,” Nanophotonics, 2018, Vol. 7, No. 5, 925-934.
2. V. Tuz, V. Khardikov, Y.?Kivshar, “All-dielectric resonant metasurfaces with a strong toroidal response,” ACS Photonics, 2018, Vol. 5, 1871-1876.
3. B. Kochetov, V. Tuz, “Induced waveform transitions of dissipative solitons,” Chaos, 2018, Vol. 28, No. 1, 013130.
4. V. Tuz, V. Khardikov, A. Kupriianov, K. Domina, S. Xu, H. Wang, H.-B. Sun, “High-quality trapped modes in all-dielectric metamaterials,” Optics Express, 2018, Vol. 26, No. 3, 2905-2916.
5. D. Novitsky, V. Tuz, S. Prosvirnin, A. Lavrinenko, A. Novitsky, “Transmission enhancement in loss-gain multilayers by resonant suppression of reflection,” Physical Review B, 2017, Vol. 96, No. 23, 235129.
6. V. Tuz, I. Fedorin, V. Fesenko, “Bi-hyperbolic isofrequency surface in a magnetic-semiconductor superlattice,” Optics Letters, 2017, Vol. 42, No. 21, 4561-4564.
7. B. Kochetov, V. Tuz, “Cascade replication of dissipative solitons,” Physical Review E, 2017, Vol. 96, No. 1, 012206.
8. V. Tuz, V. Fesenko, I. Fedorin, H.-B. Sun, W. Han, “Coexistence of bulk and surface polaritons in a magnetic-semiconductor superlattice influenced by a transverse magnetic field,” Journal of Applied Physics, 2017, Vol. 121, 103102.
9. B. Kochetov, I. Vasylieva, L. Kochetova, H.-B. Sun, V. Tuz, “Control of dissipative solitons in a magneto-optic planar waveguide,” Optics Letters, 2017, Vol. 42, No. 3, 531-534.
10. V. Tuz, V. Fesenko, I. Fedorin, H.-B. Sun, V. Shulga, “Crossing and anti-crossing effects of polaritons in a magnetic-semiconductor superlattice influenced by an external magnetic field,” Superlattices and Microstructures, 2017, 103, 285-294.
11. V. Fesenko, V. Tuz, I. Fedorin, H.-B. Sun, V. Shulga, W. Han, “Control of single-mode operation in a circular waveguide filled by a longitudinally magnetized gyroelectromagnetic medium,” Journal of Electromagnetic Waves and Applications, 2017, Vol. 31, No. 13, 1265-1276.
12. V. Tuz, V. Fesenko, I. Fedorin, H.-B. Sun, V. Shulga, W. Han, “Dispersion peculiarities of hybrid modes in a circular waveguide filled by a composite gyroelectromagnetic medium,” Journal of Electromagnetic Waves and Applications, 2017, Vol. 31, No. 2, 350-362.
13. V. Tuz, “Polaritons dispersion in a composite ferrite-semiconductor structure near gyrotropic-nihility state,” Journal of Magnetism and Magnetic Materials, 2016, 419, 559-565.
14. V. Fesenko, I. Fedorin, V.?Tuz, “Dispersion regions overlapping for bulk and surface polaritons in a magnetic-semiconductor superlattice,” Optics Letters, 2016, Vol. 41, No. 9, 2093-2096.
15. V.?Fesenko, V. Tuz, O. Shulika, I. Sukhoivanov, “Dispersion properties of Kolakoski-cladding hollow-core nanophotonic Bragg waveguide,” Nanophotonics, 2016, Vol. 5, No. 4, 500-508.
16. V. Fesenko, V. Tuz, “Dispersion blue-shift in an aperiodic Bragg reflection waveguide,” Optics Communications, 2016, 365, 225–230.
17. V. Tuz, “Gyrotropic-nihility state in a composite ferrite-semiconductor structure,” Journal of Optics, 2015, Vol. 17, No. 3, 035611.

Project

2016 – 2018  Unsteady processes in active micro- and nanostructures containing plasmon and gain components (Bilateral project of Ukrainian and Belorussian funds for fundamental researches).
2015 – 2016  Development of nonlinear metamaterials (Bilateral project of the National Academy of Sciences of Ukraine and the Scientific and Technological Research Council of Turkey).

2014 – 2016  Novel all-dielectric functional metamaterials for terahertz applications (Bilateral project of Science and Technology Center in Ukraine and the National Academy of Sciences of Ukraine).

2013 – 2014  Unsteady processes in metamaterials included active and nonlinear components (Bilateral project of Ukrainian and Belorussian funds for fundamental researches).

2010 – 2014  Research of resonance excitation of evanescent waves in periodic nanostructures made of semiconductors and superconductors (Project of the Ukrainian State program "Nanotechnologies and nanomaterials").

2009 – 2012  Research of electromagnetic wave scattering by complex periodic structures and metamaterials. Development of electrodynamic methods for designing of microstrip and waveguide phased antenna arrays (Project of National Academy of Sciences of Ukraine).

2004 – 2006  Development and approbation of computing algorithms for qualification and quantification of ischemic heart diseases (Grant of Civilian Research & Development Foundation (CRDF Global) in cooperation with CardioMag Inc., USA)