Pavel Zelenovskii
  Researcher  
   
  e-mail: zelenovskii@ua.pt  
  department: Chemistry  
   
  group: 2 - multifunctional ferroic ceramics and nanostructures
 
  line: 1 - information and communication technology
 
  direct url: https://www.ciceco.ua.pt/Zelenovskii  
  research group: Functional Imaging & Nanomaterials Laboratory  
   
Scientific interests
  • Advanced functional and nanoscale materials;
  • Supramolecular and self-assembled nanostructures;
  • Physical properties of graphene and related materials;
  • Structure and properties of organic crystals and nanostructures;
  • Phase transitions in organic and inorganic materials;
  • Ferroelectricity and piezoelectricity, ferroelectric domain structures;
  • Materials characterization: FTIR, Raman, NMR spectroscopy, AFM, XRD, SAXS, etc.
  • Data science, crystallography data mining and analysis
  • First-principle and quantum chemical calculations.
Awards and honours

2010: Young scientists award for the excellent presentation at RCBJSF’10, Yokohama, Japan.
2011: Award for the best presentation at XIX All-Russian conference on ferroelectricity, Moscow, Russia.
2012: Award of the Academia Europaea for young scientists.
2012: Medal of the Russian members club of Academia Europaea.
2016: Award of the Governor of the Sverdlovsk region (Russia) for the best work in experimental physics.
2022: Associate Member of the Royal Society of Chemistry.

Selected publications
  1. P.S. Zelenovskii, K. Romanyuk, M.S. Liberato, P. Brandão, F.F. Ferreira, S. Kopyl, W.A. Alves, A.L. Kholkin, 2D layered dipeptide crystals for piezoelectric applications, Adv. Funct. Mater., 2021, v. 31, p. 2102524.
  2. K. Romanyuk, V. Slabov, D. Alikin, P. Zelenovskiy, M.R.P. Correia, K. Keller, R.A.S. Ferreira, S. Vasilev, S. Kopyl, A. Kholkin, Piezoactive dense diphenylalanine thin films via solid-phase crystallization, Applied Materials Today, 2021, DOI: 10.1016/j.apmt.2021.101261
  3. M.S. Liberato, N.G.S. Cavalcante, P. Abinaya Sindu, M.J. Rodrigues-Jesus, P. Zelenovskii, A.C.O. Carreira, M.S. Baptista, M.C. Sogayar, L.C.S. Ferreira, L.H. Catalani, Histidine-based singlet-oxygen crosslinked hydrogels for biomedical applications, Soft Matter, 2021, v. 17, pp. 10926-10934
  4. P.S. Zelenovskiy, A.O. Davydov, A.S. Krylov, A.L. Kholkin, Raman study of structural transformations in self-assembled diphenylalanine nanotubes at elevated temperatures, J. Raman Spectrosc., 2017, v. 48, № 11, pp. 1401-1405.
  5. E. Seyedhosseini, K. Romanyuk, D. Vasileva, S. Vasilev, A. Nuraeva, P. Zelenovskiy, M. Ivanov, A.N. Morozovska, V.Ya. Shur, H. Lu, A. Gruverman, and Andrei L. Kholkin, Self-assembly of organic ferroelectrics by evaporative dewetting: a case of β-glycine, ACS Appl. Mater. Interfaces, 2017, v. 9, № 23, p. 20029.
  6. D.V. Pelegov, B.N. Slautin, V.S. Gorshkov, P.S. Zelenovskiy, E.A. Kiselev, A.L. Kholkin, and V.Y. Shur, Raman spectroscopy, ‘big data’, and local heterogeneity of solid state synthesized lithium titanate, J. Power Sources, 2017, v. 346, pp. 143-150.
  7. P. Zelenovskiy, I. Kornev, S. Vasilev, A. Kholkin, On the origin of great rigidity of self-assembled diphenylalanine nanotubes, Phys. Chem. Chem. Phys., 2016, v.18, p.29681.
  8. A. Nuraeva, S. Vasilev, D. Vasileva, P. Zelenovskiy, D. Chezganov, A. Esin, S. Kopyl, K. Romanyuk, V.Y. Shur, and A.L. Kholkin, Evaporation-Driven Crystallization of Diphenylalanine Microtubes for Microelectronic Applications, Cryst. Growth Des., 2016, v. 16(3), p. 1472-1479.
  9. S. Vasilev, P. Zelenovskiy, D. Vasileva, A. Nuraeva, V.Ya. Shur, A.L. Kholkin, Piezoelectric properties of diphenylalanine microtubes prepared from the solution, J. Phys. Chem. Solids, 2016, v.93, p.68-72.
  10. G.C. Rodrigues, P. Zelenovskiy, K. Romanyuk, S. Luchkin, Y. Kopelevich, A. Kholkin, Strong piezoelectricity in single-layer graphene deposited on SiO2 grating substrates, Nat. Comm., 2015, v.6, p.7572.
  11. H. Trivedi, V. Shvartsman, D. C. Lupascu, M. S. A. Medeiros, R. C. Pullar, A. Kholkin, P. Zelenovskiy, A. Sosnovskikh, V. Shur, Local manifestations of static magnetoelectric effect in nanostructured BaTiO3–BaFe12O9 composite multiferroic, Nanoscale, 2015, v.7, p. 4489-4496.
  12. V.Ya. Shur, P.S. Zelenovskiy, Micro- and Nanodomain Imaging in Uniaxial Ferroelectrics. Joint Application of Optical, Confocal Raman and Piezoelectric Force Microscopy, J. Appl. Phys., 2014, v.116, p. 066802.
  13. D. Isakov, D. Petukhova, S. Vasilev, A. Nuraeva, T. Khazamov, E. Seyedhosseini, P. Zelenovskiy, V. Shur, A. Kholkin, In-situ observation of the humidity controlled polymorphic phase transformation in glycine microcrystals, Cryst. Growth Des., 2014, v.14, p. 4138–4142.
  14. D. Isakov, E. de Matos Gomes, B. Almeida, A.L. Kholkin, P. Zelenovskiy, M. Neradovskiy, and V.Ya. Shur, Energy harvesting from nanofibers of hybrid organic ferroelectric dabcoHReO4, Appl. Phys. Lett., 2014, v.104, p. 032907.
  15. V.Ya. Shur, M.S. Nebogatikov, D.O. Alikin, P.S. Zelenovskiy, M.F. Sarmanova, A.V. Ievlev, E.A. Mingaliev, D.K. Kuznetsov, Investigation of the Nanodomain Structure Formation by Piezoelectric Force Microscopy and Raman Confocal Microscopy in LiNbO3 and LiTaO3 Crystals, J. Appl. Phys., 2011, v.110, p.052013-1-6.
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