Your search keyword '"Prusik, Krystian"' showing total 10 results

1. Influence of Zirconium on the Microstructure, Selected Mechanical Properties, and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (HfMo) 20−x Zr x High-Entropy Alloys.

Author

Glowka, Karsten, Zubko, Maciej, Świec, Paweł, Prusik, Krystian, Szklarska, Magdalena, and Stróż, Danuta

Subjects

CORROSION resistance, TANTALUM, ZIRCONIUM, MICROSTRUCTURE, PHYSIOLOGIC salines, SCANNING electron microscopy, ALLOYS

Abstract

The presented work considers the influence of the hafnium and molybdenum to zirconium ratio of Ti20Ta20Nb20(HfMo)20−xZrx (where x = 0, 5, 10, 15, 20 at.%) high-entropy alloys in an as-cast state for potential biomedical applications. The current research continues with our previous results of hafnium's and molybdenum's influence on a similar chemical composition. In the presented study, the microstructure, selected mechanical properties, and corrosion resistance were investigated. The phase formation thermodynamical calculations were also applied to predict solid solution formation after solidification. The calculations predicted the presence of multi-phase, body-centred cubic phases, confirmed using X-ray diffraction and scanning electron microscopy. The chemical composition analysis showed the segregation of alloying elements. Microhardness measurements revealed a decrease in microhardness with increased zirconium content in the studied alloys. The corrosion resistance was determined in Ringer's solution to be higher than that of commercially applied biomaterials. The comparison of the obtained results with previously reported data is also presented and discussed in the presented study. [ABSTRACT FROM AUTHOR]

Published

2024

2. Influence of Hafnium Addition on the Microstructure, Microhardness and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (ZrMo) 20−x Hf x (where x = 0, 5, 10, 15 and 20 at.%) High Entropy Alloys.

Author

Glowka, Karsten, Zubko, Maciej, Gębura, Sandra, Świec, Paweł, Prusik, Krystian, Szklarska, Magdalena, and Stróż, Danuta

Subjects

CORROSION resistance, ALLOY powders, HAFNIUM, BODY centered cubic structure, MOLYBDENUM, VACUUM arcs, MICROHARDNESS, ALLOYS, POWDERS

Abstract

The presented work aimed to investigate the influence of the hafnium/(zirconium and molybdenum) ratio on the microstructure, microhardness and corrosion resistance of Ti20Ta20Nb20(ZrMo)20−xHfx (where x = 0, 5, 10, 15 and 20 at.%) high entropy alloys in an as-cast state produced from elemental powder and obtained via the vacuum arc melting technique. All studied alloys contained only biocompatible elements and were chosen based on the thermodynamical calculations of phase formation predictions after solidification. Thermodynamical calculations predicted the presence of multi-phase, body-centered cubic phases, which were confirmed using X-ray diffraction and scanning electron microscopy. Segregation of alloying elements was recorded using elemental distribution maps. A decrease in microhardness with an increase in hafnium content in the studied alloys was revealed (512–482 HV1). The electrochemical measurements showed that the studied alloys exhibited a high corrosion resistance in a simulated body fluid environment (breakdown potential 4.60–5.50 V vs. SCE). [ABSTRACT FROM AUTHOR]

Published

2023

3. Crystallization Kinetics and Structure Evolution during Annealing of Ni-Co-Mn-In Powders Obtained by Mechanical Alloying.

Author

Matyja, Edyta, Prusik, Krystian, Zubko, Maciej, Świec, Paweł, Dercz, Grzegorz, and Loskot, Jan

Subjects

*CRYSTALLIZATION kinetics, *BODY centered cubic structure, *POWDERS, *ACTIVATION energy, *SHAPE memory alloys

Abstract

The crystallization kinetics and structure evolution during annealing of the Ni45.5Co4.5Mn36.6In13.4 (at. %) powders produced by mechanical alloying (MA) was investigated. After 70 h and 100 h of MA, the powder consisted of a mixture of amorphous and nanocrystalline body-centered cubic (bcc) phases. We observed the relaxation in the as-received powder. The relaxation temperature (Tre) increases logarithmically with the annealing time. Annealing above 440 °C results in (1) ordering of L21, (2) dissolution of the residual Ni and Mn, (3) tetragonal MnNi phase formation and (4) γ phases precipitation. The activation energies of the B2 → L21 and Mn (α-Mn) → MnNi (P4/mmm) transformations were calculated. [ABSTRACT FROM AUTHOR]

Published

2023

4. Influence of Molybdenum on the Microstructure, Mechanical Properties and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (ZrHf) 20−x Mo x (Where: x = 0, 5, 10, 15, 20) High Entropy Alloys.

Author

Glowka, Karsten, Zubko, Maciej, Świec, Paweł, Prusik, Krystian, Szklarska, Magdalena, Chrobak, Dariusz, Lábár, János L., and Stróż, Danuta

Subjects

MOLYBDENUM, SCANNING transmission electron microscopy, MICROSTRUCTURE, VACUUM arcs, ALLOYS, ENTROPY

Abstract

The presented work was focused on investigating the influence of the (hafnium and zirconium)/molybdenum ratio on the microstructure and properties of Ti20Ta20Nb20(ZrHf)20−xMox (where: x = 0, 5, 10, 15, 20 at.%) high entropy alloys in an as-cast state. The designed chemical composition was chosen due to possible future biomedical applications. Materials were obtained from elemental powders by vacuum arc melting technique. Phase analysis revealed the presence of dual body-centered cubic phases. X-ray diffraction showed the decrease of lattice parameters of both phases with increasing molybdenum concentration up to 10% of molybdenum and further increase of lattice parameters. The presence of two-phase matrix microstructure and hafnium and zirconium precipitates was proved by scanning and transmission electron microscopy observation. Mechanical property measurements revealed decreased micro- and nanohardness and reduced Young's modulus up to 10% of Mo content, and further increased up to 20% of molybdenum addition. Additionally, corrosion resistance measurements in Ringers' solution confirmed the high biomedical ability of studied alloys due to the presence of stable oxide layers. [ABSTRACT FROM AUTHOR]

Published

2022

5. Correlation between Microstructure and Magnetism in Ball-Milled SmCo 5 /α-Fe (5%wt. α-Fe) Nanocomposite Magnets.

Author

Bajorek, Anna, Łopadczak, Paweł, Prusik, Krystian, Zubko, Maciej, and Dell'Agli, Gianfranco

Subjects

MAGNETISM, MICROSTRUCTURE, MAGNETIC properties, SIZE reduction of materials, MAGNETIC moments

Abstract

Magnetic nanocomposites SmCo5/α-Fe were synthesized mechanically by high-energy ball milling (HEBM) from SmCo5 and 5%wt. of α-Fe powders. The X-ray diffraction analysis reveals the hexagonal 1:5 phase as the main one accompanied by the cubic α-Fe phase and 2:17 rhombohedral as the secondary phase. The content of each detected phase is modified throughout the synthesis duration. A significant decrease in crystallite size with a simultaneous increase in lattice straining is observed. A simultaneous gradual reduction in particle size is noted from the microstructural analysis. Magnetic properties reveal non-linear modification of magnetic parameters associated with the strength of the exchange coupling induced by various duration times of mechanical synthesis. The highest value of the maximum energy product (BH)max at room temperature is estimated for samples milled for 1 and 6 h. The intermediate mixed-valence state of Sm ions is confirmed by electronic structure analysis. An increase in the Co magnetic moment versus the milling time is evidenced based on the performed fitting of the Co3s core level lines. [ABSTRACT FROM AUTHOR]

Published

2021

6. Analysis of Stainless Steel Waste Products Generated during Laser Cutting in Nitrogen Atmosphere.

Author

Zubko, Maciej, Loskot, Jan, Świec, Paweł, Prusik, Krystian, and Janikowski, Zbigniew

Subjects

LASER beam cutting, STEEL wastes, ATMOSPHERIC nitrogen, WASTE products, MATERIALS, ELECTRON energy loss spectroscopy, STAINLESS steel

Abstract

Laser cutting technology is one of the basic approaches used for thermal processing of parts fabricated from almost all engineering materials. Various types of lasers are utilized in the industry with different attendant gases such as nitrogen or argon. When the laser beam interacts with a metal surface, the area underneath is heated to the melting point. This liquid or vaporized metal is ejected from the kerf area to the surrounding atmosphere by attendant gas and becomes undesirable waste in the form of powder. In the presented work, the X-ray diffraction, scanning electron microscopy, electron backscatter diffraction, transmission electron microscopy, and energy-dispersive X-ray spectroscopy methods were used to analyze AISI 304 stainless steel, which was cut by a semiconductor fiber laser, and the waste powder generated during the laser cutting process. The results suggest that this waste material may be reused for industrial applications such as additive manufacturing. [ABSTRACT FROM AUTHOR]

Published

2020

7. Microstructure and Mechanical Properties of Co-Cr-Mo-Si-Y-Zr High Entropy Alloy.

Author

Glowka, Karsten, Zubko, Maciej, Świec, Paweł, Prusik, Krystian, Albrecht, Robert, Dercz, Grzegorz, Loskot, Jan, Witala, Bartosz, and Stróż, Danuta

Subjects

SOLID-state phase transformations, NANOINDENTATION, MICROSTRUCTURE, VACUUM arcs, DENDRITIC crystals, ALLOYS, COBALT nickel alloys

Abstract

Presented work was focused on obtaining new, up to our knowledge, non-described previously in the literature high entropy Co15Cr15Mo25Si15Y15Zr15 alloy to fill in the knowledge gap about the six-elemental alloys located in the adjacent to the center of phase diagrams. Material was obtained using vacuum arc melting. Phase analysis revealed the presence of a multi-phase structure. Scanning electron microscopy microstructure analysis revealed the existence of three different phases with partially dendritic structures. Chemical analysis showed that all phases consist of all six principal elements—however, with different proportions. Transmission electron microscopy microstructure analysis confirmed the presence of amorphous and nanocrystalline areas, as well as their mixture. For the studied alloy, any phase transformation and solid-state crystallization were not revealed in the temperature range from room temperature up to 1350 °C. Nanoindentation measurements revealed high nanohardness (13(2) GPa and 18(1) GPa for dendritic and interdendritic regions, respectively) and relatively low Young's modulus (185(23) GPa and 194(9) GPa for dendritic and interdendritic regions, respectively) of the observed phases. [ABSTRACT FROM AUTHOR]

Published

2020

8. Influence of Zirconium on the Microstructure, Selected Mechanical Properties, and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (HfMo) 20-x Zr x High-Entropy Alloys.

Author

Glowka K, Zubko M, Świec P, Prusik K, Szklarska M, and Stróż D

Abstract

The presented work considers the influence of the hafnium and molybdenum to zirconium ratio of Ti 20 Ta 20 Nb 20 (HfMo) 20-x Zr x (where x = 0, 5, 10, 15, 20 at.%) high-entropy alloys in an as-cast state for potential biomedical applications. The current research continues with our previous results of hafnium's and molybdenum's influence on a similar chemical composition. In the presented study, the microstructure, selected mechanical properties, and corrosion resistance were investigated. The phase formation thermodynamical calculations were also applied to predict solid solution formation after solidification. The calculations predicted the presence of multi-phase, body-centred cubic phases, confirmed using X-ray diffraction and scanning electron microscopy. The chemical composition analysis showed the segregation of alloying elements. Microhardness measurements revealed a decrease in microhardness with increased zirconium content in the studied alloys. The corrosion resistance was determined in Ringer's solution to be higher than that of commercially applied biomaterials. The comparison of the obtained results with previously reported data is also presented and discussed in the presented study.

Published

2024

9. Influence of Hafnium Addition on the Microstructure, Microhardness and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (ZrMo) 20-x Hf x (where x = 0, 5, 10, 15 and 20 at.%) High Entropy Alloys.

Author

Glowka K, Zubko M, Gębura S, Świec P, Prusik K, Szklarska M, and Stróż D

Abstract

The presented work aimed to investigate the influence of the hafnium/(zirconium and molybdenum) ratio on the microstructure, microhardness and corrosion resistance of Ti 20 Ta 20 Nb 20 (ZrMo) 20-x Hf x (where x = 0, 5, 10, 15 and 20 at.%) high entropy alloys in an as-cast state produced from elemental powder and obtained via the vacuum arc melting technique. All studied alloys contained only biocompatible elements and were chosen based on the thermodynamical calculations of phase formation predictions after solidification. Thermodynamical calculations predicted the presence of multi-phase, body-centered cubic phases, which were confirmed using X-ray diffraction and scanning electron microscopy. Segregation of alloying elements was recorded using elemental distribution maps. A decrease in microhardness with an increase in hafnium content in the studied alloys was revealed (512-482 HV1). The electrochemical measurements showed that the studied alloys exhibited a high corrosion resistance in a simulated body fluid environment (breakdown potential 4.60-5.50 V vs. SCE).

Published

2023

10. Influence of Molybdenum on the Microstructure, Mechanical Properties and Corrosion Resistance of Ti 20 Ta 20 Nb 20 (ZrHf) 20-x Mo x (Where: x = 0, 5, 10, 15, 20) High Entropy Alloys.

Author

Glowka K, Zubko M, Świec P, Prusik K, Szklarska M, Chrobak D, Lábár JL, and Stróż D

Abstract

The presented work was focused on investigating the influence of the (hafnium and zirconium)/molybdenum ratio on the microstructure and properties of Ti 20 Ta 20 Nb 20 (ZrHf) 20 -x Mo x (where: x = 0, 5, 10, 15, 20 at.%) high entropy alloys in an as-cast state. The designed chemical composition was chosen due to possible future biomedical applications. Materials were obtained from elemental powders by vacuum arc melting technique. Phase analysis revealed the presence of dual body-centered cubic phases. X-ray diffraction showed the decrease of lattice parameters of both phases with increasing molybdenum concentration up to 10% of molybdenum and further increase of lattice parameters. The presence of two-phase matrix microstructure and hafnium and zirconium precipitates was proved by scanning and transmission electron microscopy observation. Mechanical property measurements revealed decreased micro- and nanohardness and reduced Young's modulus up to 10% of Mo content, and further increased up to 20% of molybdenum addition. Additionally, corrosion resistance measurements in Ringers' solution confirmed the high biomedical ability of studied alloys due to the presence of stable oxide layers.

Published

2022