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Multi-element Systems of Biomaterials Based on Magnesium and Zinc
Hasoňová, Michaela ; Nový, František (referee) ; Vojtěch, Dalibor (referee) ; Doležal, Pavel (advisor)
Dissertation thesis deals with basic research in the field of materials from pure Zn powders and Mg, Zn, and Ca binary mixtures prepared by powder metallurgy. General powder metallurgy principles and methods, a brief description of Mg, Zn, and Ca structure and properties, and the latest research in the field of bulk materials preparation from these elements via powder metallurgy are summarized in the theoretical part of the thesis. The experimental part focuses on the preparation of materials from finer and coarser Zn powder particles by hot pressing at 300 and 400 °C using the pressure of 100, 200, 300, 400, and 500 MPa. Binary mixtures based on Mg with the addition of Zn or Ca were prepared by hot pressing in the solid-state (300 °C) and hot pressing in the semi-solid state (400 °C, 450 °C in the case of Mg-Ca system) using the pressure of 500 MPa. Binary mixtures based on Zn with the addition of Mg or Ca were prepared by hot pressing in the semi-solid state (400 °C) using the pressure of 500 MPa. The prepared materials were evaluated in terms of microstructure, elemental and phase composition, microhardness, flexural strength, and fractography. The results showed that in the case of processed from pure Zn powders, a better combination of the flexural strength and displacement was achieved in the case of the finer Zn powder, namely in the material prepared at a temperature of 400 °C and a pressure of 500 MPa. In the case of mixtures, the best connection between the powder particles was achieved in the case of a material based on finer Zn powder with 0.5 wt.% of Mg, which had a significant effect on the achieved values of flexural strength and displacement. The amount of minor powder in the mixture had a significant effect on the prepared material structure and phase composition, while the processing conditions influenced the reached strength characteristics and fracture mechanism.
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ELECTROCHEMICAL CHARACTERISTICS OF ADVANCED MAGNESIUM ALLOYS PROCESSED BY POWDER METALURGY
Minda, Jozef ; Nový, František (referee) ; Stoulil, Jan (referee) ; Hadzima,, Branislav (advisor)
The subject of the present dissertation is basic research in the field of advanced magnesium-based materials with high potential for medical applications prepared by powder metallurgy. These materials are evaluated in terms of corrosion behaviour in corrosive media by chemical composition and set conditions simulating the physiological environment of the human body (Hank's Balanced Salt Solution was used in this work). The aim is to analyze the influence of the processing parameters, chemical composition and structure on electrochemic characteristics of theprepared materials. For this purpose, a deeper of the the corrosion behavior, to obtain electrochemical characteristics and to investigate the degradation properties of the studied materials by means of electrochemical impedance spectroscopy (EIS), scanning electron microscopy (SEM), with elemental analysis by energy-dispersive spectroscopy (EDS) and other complementary methods. The materials for the experiments are prepared using powder metallurgy, which allows the formation of composites with compositions that do not match conventional manufacturing technologies. Thus, pure Mg samples were prepared at process parameters with pressing pressures of 100 and 500 MPa at 400 °C and also samples pressed at 500 MPa and room temperature were tested. Furthermore, MgZn composites prepared at a pressing pressure of 500 MPa and a temperature of 300 °C with a Zn content of 1, 5, 10 and 15 wt.% or MgZn composites pressed at a pressure of 500 MPa and a temperature of 400 °C with a Zn content of 1, 5 and 10 wt.%. Composites of the Mg-hydroxyapatite binary system pressed at 500 MPa and 400 °C with hydroxyapatite contents of 10, 20, 30 and 40 wt.% were also studied. The degradation mechanisms of these materials were investigated using the above mentioned methods and the basic electrochemical parameters and their evolution during the time of exposure were determined. From the results, the influence of process parameters, chemical composition and the corrosive environment itself on the studied materials is evaluated. Several materials that appear to be most suitable for the medical application are described and the causes of degradation behaviour at the level of the structure of the materials and their electrochemical interaction with the corrosive environment are also discussed in the dissertation thesis. Compaction and densification positively influenced pure Mg samples, where samples pressed at 500 MPa and 400 °C are further selected as reference material. Increasing Zn content positively electrochemically affects the corrosion resistance of MgZn series of samples pressed at 500 MPa and 300 °C, on the contrary, in the combination of electrochemical - microgalvanic and structural effects, low Zn content is optimal for MgZn composites pressed at 500 MPa and 400 °C. For Mg-hydroxyapatite materials, in agreement with the literature, it was shown that the most stable corrosion product layers with the best corrosion properties and evolution in time are formed for samples with hydroxyapatite content up to 10 wt.%.
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Microstructural investigations of novel high entropy alloys
Vlasák, Tomáš ; Čížek, Jakub (advisor) ; Nový, František (referee) ; Moreira, Afonso (referee)
High entropy alloys constitute a novel approach in materials research. In this thesis, four novel alloys (namely NbTaTiZr, HfNbTaTiZr, HfNbTiVZr and HfNbTaTiVZr) are investigated. Their microstructure and mechanical properties are studied both in the as-cast and the annealed state. It is shown that their strengthening is caused by lattice distortions, which are the result of random filling of lattice sites by atoms of various elements with different atomic radii. Furthermore, positron annihilation investigations revealed that positrons actively search for open volumes in interstitial regions associated with lattice distortions, and therefore lattice distortions can be characterised by positron lifetimes.
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Investigation of titanium alloys using neutron diffraction
Németh, Gergely ; Mathis, Kristián (advisor) ; Nový, František (referee) ; Seiner, Hanuš (referee)
Title: Investigation of titanium alloys using neutron diffraction Author: Gergely Németh Department / Institute: Department of Physics of Materials Supervisor of the master thesis: prof. RNDr. Kristián Mathis, Ph.D., DrSc., Department of Physics of Materials Abstract: Titanium grade 2 was treated by multiple passes of the continuous equal- channel angular pressing technique (CONFORM ECAP) and, after each pass, additionally by rotary swaging. The residual strain field in samples processed by only CONFORM ECAP was studied by neutron diffraction strain scanning. In order to elucidate the microscopic background and calculate the related residual stress field, the local microstructure was thoroughly investigated by various experimental techniques. The microstructure and the deformation behavior of the rotary swaged samples was studied by transmission electron microscopy and by in-situ neutron diffraction during compression. The results of the analyses indicated that microstructural gradients were present in the material as the result of the inhomogeneous deformation during the CONFORM ECAP treatment. These gradients were identified as the main reason of the presence of residual stress fields. The distributions of stress fields calculated based on microstructural parameters were in correlation with simulation...
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Multi-element Systems of Biomaterials Based on Magnesium and Zinc
Hasoňová, Michaela ; Nový, František (referee) ; Vojtěch, Dalibor (referee) ; Doležal, Pavel (advisor)
Dissertation thesis deals with basic research in the field of materials from pure Zn powders and Mg, Zn, and Ca binary mixtures prepared by powder metallurgy. General powder metallurgy principles and methods, a brief description of Mg, Zn, and Ca structure and properties, and the latest research in the field of bulk materials preparation from these elements via powder metallurgy are summarized in the theoretical part of the thesis. The experimental part focuses on the preparation of materials from finer and coarser Zn powder particles by hot pressing at 300 and 400 °C using the pressure of 100, 200, 300, 400, and 500 MPa. Binary mixtures based on Mg with the addition of Zn or Ca were prepared by hot pressing in the solid-state (300 °C) and hot pressing in the semi-solid state (400 °C, 450 °C in the case of Mg-Ca system) using the pressure of 500 MPa. Binary mixtures based on Zn with the addition of Mg or Ca were prepared by hot pressing in the semi-solid state (400 °C) using the pressure of 500 MPa. The prepared materials were evaluated in terms of microstructure, elemental and phase composition, microhardness, flexural strength, and fractography. The results showed that in the case of processed from pure Zn powders, a better combination of the flexural strength and displacement was achieved in the case of the finer Zn powder, namely in the material prepared at a temperature of 400 °C and a pressure of 500 MPa. In the case of mixtures, the best connection between the powder particles was achieved in the case of a material based on finer Zn powder with 0.5 wt.% of Mg, which had a significant effect on the achieved values of flexural strength and displacement. The amount of minor powder in the mixture had a significant effect on the prepared material structure and phase composition, while the processing conditions influenced the reached strength characteristics and fracture mechanism.
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