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Nepřihlášený uživatel
You are here: VŠCHT PrahaFCHTÚKMKI  → Staff → doc. Ing. Filip Průša, Ph.D.

doc. Ing. Filip Průša, Ph.D.

Phone: +420220444441
Room: A55
Scopus ID: 23478092600

Title: Associate professor

Education:

  • 2009-2016: University of Chemical Technology, Prague, doctoral stage, study field Metallurgy.
  • 2007-2010: University of Chemical Technology, Prague, bachelor's stage, study field Process Engineering, Informatics and Management.
  • 2007-2009: University of Chemical Technology, Prague, follow-up master's stage, study field Metallic Materials
  • 2004-2007: University of Chemical Technology, Prague, bachelor's stage, study field Chemistry and Materials Technology.

Career:

  • since 2023: UCT Prague, Institute of Metals and Corrosion Engineering, Associate Professor
  • since 2016: UCT Prague, Institute of Metals and Corrosion Engineering, Assistant Professor
  • 01/2017-12/2018: Institute of Physics of the Czech Academy of Sciences, Prague, Department of Functional Materials, Postdoctoral Fellow
  • 2009-2016: UCT Prague, Institute of Metals and Corrosion Engineering, Research Fellow
  • 2011-2013: UCT Prague, Member of the Grant Board of the Institute of Chemical Technology Prague.

Specialization:

  • rapid solidification of metals
  • powder metallurgy
  • aluminium alloys
  • titanium alloys
  • high entropy alloys
  • biodegradable Zn alloys
  • plasma sintering

Lectures:

  • Material Degradation
  • Conservation-Restoration Informatics
  • Corrosion and Degradation of Metals
  • Laboratory Project I
  • Laboratory Project II
  • Laboratory of Specialization (rapid solidification, plasma sintering, mechanical alloying)

Membership in professional organizations and editorial boards:

  • member of the Czechoslovak Microscopy Society
  • member of the European Microscopy Society
  • member of the Microscopy Society of America

Research Projects:

  • 2024-2026 (GAČR; 25-15757S): Plazmové zhodnocení odpadu na pokročilé cermetové kompozity pro vysokou disipaci kinetické energie (investigator).
  • 2024-2026 (GAČR; 24-10767S): Pokročilé slitiny s vysokou entropií vyztužené pomocí in-situ připravených karbidů z různých typů nanostrukturovaných uhlíkových prekurzorů (investigator).
  • 2022-2025 (TAČR; TK04020056): Vysokoteplotní odolné materiály pro komponenty tepelných okruhů (co-investigator).

Notable magazine contributions:

  1. Kratochvíl, P., H. Thürlová, V. Nováček, A. Strakošová, J. Čech, M. Karlík, P. Haušild, J. Čapek, and F. Průša. Understanding the influence of Ti content on mechanically alloyed and sintered CoCrFeNiTix high entropy alloy, (2025) Journal of Materials Research and Technology 35 7371-7383, https://doi.org/10.1016/j.jmrt.2025.03.032.
  2. Ashtiani, S., T. Přibyl, J. Schneider, M. Khoshnamvand, F. Průša, T. Ruml, J. Floreková, D. Gardenӧ, J. Zelenka, Z. Sofer, and K. Friess. Unveiling the effect of surface modification of spherical PVDF nanoparticles via ZIF-8 and NH2 functional groups on gas adsorption and cell nanotoxicity, (2025) Environmental Research 274 121234, htttps://doi.org/https://doi.org/10.1016/j.envres.2025.121234.
  3. Paidar, V., A. Strakosova, F. Průša, D. Dvorský, and P. Lejček. Interpretation of plastic deformation of copper particles in silver, (2025) Materials Letters 378 https://doi.org/10.1016/j.matlet.2024.137601.
  4. Strakosova, A., F. Průša, P. Jiříček, J. Houdková, A. Michalcová, and D. Vojtěch. High-temperature exposure of the high-strength 18Ni-300 maraging steel manufactured by laser powder bed fusion: oxidation, structure and mechanical changes, (2024) Journal of Materials Science 59 (33), 15859-15882, https://doi.org/10.1007/s10853-024-10102-y.
  5. Strakosova, A., D. Dvorský, F. Průša, E. Alarcon, M. Roudnická, V. Paidar, S. Habr, J. Svoboda, I. Sedlářová, and P. Lejček. Structure and plastic deformation of metastable Ag–Cu metal-matrix composites produced by a bottom-up way from Cu@Ag core–shell powders, (2024) Journal of Materials Science 59 (31), 14728-14746, https://doi.org/10.1007/s10853-024-10053-4.
  6. Průša, F., P. Kratochvíl, A. Strakošová, M. Karlík, A. Školáková, J. Čech, P. Haušild, J. Čapek, M. Vronka, J. Veselý, H. Thürlová, M. Cabibbo, and O. Jankovský. Microstructure and mechanical properties of in-situ SiO2-reinforced mechanically alloyed CoCrFeNiMnX (X= 5, 20, 35 at.%) high-entropy alloys, (2024) Journal of Materials Research and Technology 32 860-873, https://doi.org/10.1016/j.jmrt.2024.07.172.
  7. Kratochvíl, P., F. Průša, H. Thürlová, A. Strakošová, M. Karlík, J. Čech, P. Haušild, J. Čapek, O. Ekrt, M. Jarošová, M. Vronka, J. Veselý, P. Minárik, O. Jankovský, and M. Cabibbo. The role of the preparation route on microstructure and mechanical properties of AlCoCrFeNi high entropy alloy, (2024) Journal of Materials Research and Technology 30 4248-4260, https://doi.org/10.1016/j.jmrt.2024.04.090.
  8. Průša, F., P. Kratochvíl, H. Thürlová, D. Rudomilova, and Š. Msallamová. Influence of the Mn Content on the Corrosion Behaviour of HEA CoCrFeNiMnX (X=5, 20, 35 at.%) Prepared via MA+SPS, (2023) Manufacturing Technology 23 (2), 247-253, https://doi.org/10.21062/mft.2023.016.
  9. Pavlík, Z., M. Záleská, M. Pavlíková, A. Pivák, J. Nábělková, O. Jankovský, A. Jiříčková, O. Chmel, and F. Průša. Simultaneous Immobilization of Heavy Metals in MKPC-Based Mortar—Experimental Assessment, (2023) Materials 16 (24), https://doi.org/10.3390/ma16247525.
  10. Novák, P., J. Duda, F. Průša, K. Skotnicová, I. Szurman, and B. Smetana. Synthesis of FeSi–FeAl Composites from Separately Prepared FeSi and FeAl Alloys and Their Structure and Properties, (2023) Materials 16 (24), https://doi.org/10.3390/ma16247685.
  11. Karlík, M., F. Průša, P. Kratochvíl, H. Thürlová, A. Strakošová, J. Čech, J. Čapek, M. Vronka, M. Cabibbo, and O. Ekrt. Microstructure and Mechanical Properties of Spark Plasma Sintered CoCrFeNiNbX High-Entropy Alloys with Si Addition, (2023) Materials 16 (6), https://doi.org/10.3390/ma16062491.
  12. Voňavková, I., F. Průša, J. Kubásek, A. Michalcová, and D. Vojtěch. Microstructure and Mechanical Properties of Ti-25Nb-4Ta-8Sn Alloy Prepared by Spark Plasma Sintering, (2022) Materials 15 (6), https://doi.org/10.3390/ma15062158.
  13. Thürlová, H. and F. Průša. Partial Substitution of Mn by Al in the Cocrfenimnxal20-X (X=5, 10, 15) High Entropy Alloy Prepared of Mechanical Alloying and Spark Plasma Sintering, (2022) Manufacturing Technology 22 (3), 342-346, https://doi.org/10.21062/mft.2022.045.
  14. Thürlová, H. and F. Průša. Influence of the Al Content on the Properties of Mechanically Alloyed CoCrFeNiMnXAl20−X High-Entropy Alloys, (2022) Materials 15 (22), https://doi.org/10.3390/ma15227899.
  15. Strakosova, A., F. Průša, A. Michalcová, P. Kratochvíl, and D. Vojtěch. Annealing Response of Additively Manufactured High-Strength 1.2709 Maraging Steel Depending on Elevated Temperatures, (2022) Materials 15 (11), https://doi.org/10.3390/ma15113753.
  16. Strakosova, A., P. Kratochvíl, J. Riedl, and F. Průša. Phase and Mechanical Properties Response of the Mechanically Alloyed CoCrFeNiAlX High Entropy Alloys, (2022) Manufacturing Technology 22 (4), 471-476, https://doi.org/10.21062/mft.2022.059.
  17. Reznickova, A., H.Y. Nguyenova, K. Zaruba, J. Strasakova, Z. Kolska, A. Michalcova, F. Prusa, O. Kvitek, P. Slepicka, P. Sajdl, and V. Svorcik. Grafting of silver nanospheres and nanoplates onto plasma activated PET: Effect of nanoparticle shape on antibacterial activity, (2022) Vacuum 203 https://doi.org/10.1016/j.vacuum.2022.111268.
  18. Regmi, C., S. Ashtiani, F. Průša, and K. Friess. Synergistic effect of hybridized TNT@GO fillers in CTA-based mixed matrix membranes for selective CO2/CH4 separation, (2022) Separation and Purification Technology 282 https://doi.org/10.1016/j.seppur.2021.120128.
  19. Lovaši, T., V. Pečinka, J. Ludvík, J. Kubásek, F. Průša, and M. Kouřil. Corrosion Properties of Boron- and Manganese-Alloyed Stainless Steels as a Material for the Bipolar Plates of PEM Fuel Cells, (2022) Materials 15 (19), https://doi.org/10.3390/ma15196557.
  20. Kratochvíl, P. and F. Průša. CoCrFeNiTi High Entropy Alloy Prepared via Mechanical Alloying and Spark Plasma Sintering, (2022) Manufacturing Technology 22 (4), 423-428, https://doi.org/10.21062/mft.2022.049.
  21. Jakeš, V., J. Havlíček, F. Průša, R. Kučerková, M. Nikl, and K. Rubešová. Translucent LiSr4(BO3)3 ceramics prepared by spark plasma sintering, (2022) Ceramics International 48 (11), 15785-15790, https://doi.org/10.1016/j.ceramint.2022.02.116.
  22. Havlícek, J., K. Rubešová, V. Jakeš, J. Cajzl, F. Pruša, R. Kucerková, and M. Nikl. Eu-DOPED La1xYxAlO3: Impact of Y/La ratio on optical properties, (2022) Ceramics - Silikaty 66 (1), 78-84, https://doi.org/10.13168/cs.2022.0002.
  23. Čech, J., J. Čapek, F. Průša, and P. Haušild. Effect of the Processing Routes on the Properties of CoCrFeMnNi Alloy. in Powder Metallurgy Progress. 2022.
  24. Ashtiani, S., C. Regmi, J. Azadmanjiri, N.V. Hong, V. Fíla, F. Průša, Z. Sofer, and K. Friess. Stimuli-responsive of magnetic metal-organic frameworks (MMOF): Synthesis, dispersion control, and its tunability into polymer matrix under the augmented-magnetic field for H2 separation and CO2 capturing applications, (2022) International Journal of Hydrogen Energy 47 (46), 20166-20175, https://doi.org/10.1016/j.ijhydene.2022.04.120.
Updated: 31.3.2025 14:59, Author: Hana Thürlová

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